The SR/ER-mitochondria calcium crosstalk is regulated by GSK3β during reperfusion injury

Glycogen synthase kinase-3β (GSK3β) is a multifunctional kinase whose inhibition is known to limit myocardial ischemia–reperfusion injury. However, the mechanism mediating this beneficial effect still remains unclear. Mitochondria and sarco/endoplasmic reticulum (SR/ER) are key players in cell death signaling. Their involvement in myocardial ischemia–reperfusion injury has gained recognition recently, but the underlying mechanisms are not yet well understood. We questioned here whether GSK3β might have a role in the Ca²⁺ transfer from SR/ER to mitochondria at reperfusion. We showed that a fraction of GSK3β protein is localized to the SR/ER and mitochondria-associated ER membranes (MAMs) in the heart, and that GSK3β specifically interacted with the inositol 1,4,5-trisphosphate receptors (IP₃Rs) Ca²⁺ channeling complex in MAMs. We demonstrated that both pharmacological and genetic inhibition of GSK3β decreased protein interaction of IP₃R with the Ca²⁺ channeling complex, impaired SR/ER Ca²⁺ release and reduced the histamine-stimulated Ca²⁺ exchange between SR/ER and mitochondria in cardiomyocytes. During hypoxia reoxygenation, cell death is associated with an increase of GSK3β activity and IP₃R phosphorylation, which leads to enhanced transfer of Ca²⁺ from SR/ER to mitochondria. Inhibition of GSK3β at reperfusion reduced both IP₃R phosphorylation and SR/ER Ca²⁺ release, which consequently diminished both cytosolic and mitochondrial Ca²⁺ concentrations, as well as sensitivity to apoptosis. We conclude that inhibition of GSK3β at reperfusion diminishes Ca²⁺ leak from IP₃R at MAMs in the heart, which limits both cytosolic and mitochondrial Ca²⁺ overload and subsequent cell death.Glycogen synthase kinase-3 (GSK3) was originally identified as a phosphorylating kinase for glycogen synthase.^{1, 2} It has two isoforms, α and β, that possess strong homology in their kinase domains with, however, distinct functions.³ GSK3 is constitutively active but it can be inhibited by phosphorylation on serine 21 (Ser21) for GSK3α and Ser9 for GSK3β.⁴ In the heart, GSK3β has several important roles in cardiac hypertrophy⁵ and ischemia–reperfusion (IR) injury.⁶ Accumulating evidence indicates that phospho-Ser9-GSK3β-mediated cytoprotection is achieved by an increased threshold for permeability transition pore (PTP) opening.^{6, 7, 8, 9} The mechanism by which GSK3β delays PTP opening still remains unclear. It has been reported that GSK3β could interact with ANT at the inner mitochondrial membrane in the heart⁹ and/or to phosphorylate voltage-dependent anion channel (VDAC) and cyclophilin D (CypD) in cancer cells.^{10, 11} GSK3β also has other proposed mechanisms of action, including a poorly characterized role in calcium (Ca²⁺) homeostasis regulation¹² and protein–protein interactions,⁹ as well as functions in different subcellular fractions such as the nucleus, cytosol and mitochondria.¹³Reperfusion is the most powerful intervention to salvage ischemic myocardium. However, it can also paradoxically lead to cardiomyocyte injury and death.¹⁴ One of the main actors of this lethal reperfusion injury is cellular Ca²⁺ overload,¹⁵ which results in part from excessive sarco/endoplasmic reticulum (SR/ER) Ca²⁺ release and Ca²⁺ influx through the plasma membrane (e.g. through L-type Ca²⁺channel and NCX (sodium-calcium exchanger)).¹⁶ Although ryanodine receptors (RyRs) are the major cardiac SR/ER Ca²⁺-release channels involved in excitation–contraction coupling (ECC)¹⁷ and ischemia–reperfusion (IR) injury,¹⁸ recent studies reported an increasing role for inositol 1,4,5-trisphosphate receptors (IP₃Rs) Ca²⁺-release channels in the modulation of ECC and cell death.^{19, 20} Ca²⁺-handling proteins of ER and mitochondria are highly concentrated at mitochondria-associated ER membranes (MAMs), providing a direct and proper mitochondrial Ca²⁺ signaling, including VDAC, Grp75 and IP₃R1.^{20, 21, 22}Here, we provide evidence that, following IR, a fraction of cellular GSK3β is localized at the SR/ER and MAMs. At the MAMs interface, GSK3β can specifically interact and regulate the protein composition of the IP₃R Ca²⁺ channeling complex and modulate Ca²⁺ transfer between SR/ER and mitochondria. These findings support a novel mechanism of action of GSK3β in cell death process during reperfusion injury.     

TRPC1-mediated Ca2+ entry is essential for the regulation of hypoxia and nutrient depletion-dependent autophagy

Autophagy is a cellular catabolic process needed for the degradation and recycling of protein aggregates and damaged organelles. Although Ca²⁺ is suggested to have an important role in cell survival, the ion channel(s) involved in autophagy have not been identified. Here we demonstrate that increase in intracellular Ca²⁺ via transient receptor potential canonical channel-1 (TRPC1) regulates autophagy, thereby preventing cell death in two morphologically distinct cells lines. The addition of DMOG or DFO, a cell permeable hypoxia-mimetic agents, or serum starvation, induces autophagy in both epithelial and neuronal cells. The induction of autophagy increases Ca²⁺ entry via the TRPC1 channel, which was inhibited by the addition of 2APB and {"type":"entrez-protein","attrs":{"text":"SKF96365","term_id":"1156357400","term_text":"SKF96365"}}SKF96365. Importantly, TRPC1-mediated Ca²⁺ entry resulted in increased expression of autophagic markers that prevented cell death. Furthermore, hypoxia-mediated autophagy also increased TRPC1, but not STIM1 or Orai1, expression. Silencing of TRPC1 or inhibition of autophagy by 3-methyladenine, but not TRPC3, attenuated hypoxia-induced increase in intracellular Ca²⁺ influx, decreased autophagy, and increased cell death. Furthermore, the primary salivary gland cells isolated from mice exposed to hypoxic conditions also showed increased expression of TRPC1 as well as increase in Ca²⁺ entry along with increased expression of autophagic markers. Altogether, we provide evidence for the involvement of Ca²⁺ influx via TRPC1 in regulating autophagy to protect against cell death.Autophagy is a cellular process responsible for the delivery of proteins or organelles to lysosomes for its degradation. Autophagy participates not only in maintaining cellular homeostasis, but also promotes cell survival during cellular stress situations.^{1, 2} The stress conditions including nutrient starvation, hypoxia conditions, invading microbes, and tumor formation, have been shown to induce autophagy that allows cell survival in these stressful or pathological situations.¹ In addition, autophagy also recycles existing cytoplasmic components to generate the molecules that are required to sustain the most vital cellular functions.³ Till date, three forms of autophagy have been identified, which are designated as chaperone-mediated autophagy, microautophagy, and macroautophagy.⁴ Although the precise mechanism as to how autophagy is initiated is not well understood, many of the genes first identified in yeast that are involved in autophagy have orthologs in other eukaryotes including human homologs.^{5, 6} The presence of similar genes in all organisms suggests that autophagy might be a phenomenon that is evolutionally conserved that is essential for cell survival. In addition, since autophagy delivers a fresh pool of amino acids and other essential molecules to the cell, initiation of autophagy is highly beneficial particularly during nutritional stress situations or tissue remodeling during development and embryogenesis.⁶ Consequently, impaired or altered autophagy is often implicated in several pathologies, like neurodegenerative disorders and cancer,^{7, 8, 9} which again highlight its importance.Ca²⁺ has a vital role in the regulation of a large number of cellular processes such as cell proliferation, survival, migration, invasion, motility, and apoptosis.^{10, 11} To perform functions on such a broad spectrum, the cells have evolved multiple mechanisms regulating cellular Ca²⁺ levels, mainly by regulating the function of various Ca²⁺ channels present in different locations. Mitochondrial, ER, lysosomal, and cytosolic Ca²⁺ levels are regulated by Ca²⁺ permeable ion channels localized either on the membranes of the intracellular organelles or on the plasma membrane.¹⁰ The Ca²⁺ permeable channels, including families of TRPCs, Orais, voltage-gated, two-pore, mitochondrial Ca²⁺ uniporter, IP₃, and ryanodine receptors have all been identified to contribute towards changes in intracellular Ca²⁺ ([Ca²⁺]_i).^{10, 12, 13, 14} Channels of the TRPCs and Orai families have been related to several Ca²⁺-dependent physiological processes in various cell types, ranging from cell proliferation to contractility, to apoptosis under both physiological and pathological conditions.¹² Moreover, it has been suggested that intracellular Ca²⁺ is one of the key regulators of autophagy;¹⁵ however, the possible role of Ca²⁺ in autophagy is still inconclusive. Many reports also suggest that Ca²⁺ inhibits autophagy,^{16, 17, 18} whereas others have indicated a stimulatory role for Ca²⁺ towards autophagy.^{19, 20, 21} Furthermore, the identity of the major Ca²⁺ channel(s) involved in autophagy is not known. Members of the TRPC family have been suggested as mediators of Ca²⁺ entry into cells. Activation of the G-protein (G_q/11–PLC pathway) leads to the generation of second messenger IP₃.^{10, 22} IP₃ binds to the IP₃R, which initiates Ca²⁺ release from the ER stores, thereby facilitating stromal interacting molecule-1 (STIM1) to rearrange and activate Ca²⁺ entry via the store-operated channels.²² Two families of proteins (TRPCs and Orais) have been identified as potential candidates for SOC-mediated Ca²⁺ entry.^{12, 22} However, their role in autophagy has not yet been determined. Thus, here we investigated the role of Ca²⁺ entry channels (TRPCs and Orais) in autophagy and show that both hypoxia-mimetic and nutrient depression induces autophagy in two different cell lines. Furthermore, our data indicates that autophagy was dependent on TRPC1-mediated increase in intracellular Ca²⁺ levels, suggesting that TRPC1 has an important role in regulating autophagy and inhibiting cell death.     

Differential Sodium and Potassium Transport Selectivities of the Rice OsHKT2;1 and OsHKT2;2 Transporters in Plant Cells

Na⁺ and K⁺ homeostasis are crucial for plant growth and development. Two HKT transporter/channel classes have been characterized that mediate either Na⁺ transport or Na⁺ and K⁺ transport when expressed in Xenopus laevis oocytes and yeast. However, the Na⁺/K⁺ selectivities of the K⁺-permeable HKT transporters have not yet been studied in plant cells. One study expressing 5′ untranslated region-modified HKT constructs in yeast has questioned the relevance of cation selectivities found in heterologous systems for selectivity predictions in plant cells. Therefore, here we analyze two highly homologous rice (Oryza sativa) HKT transporters in plant cells, OsHKT2;1 and OsHKT2;2, that show differential K⁺ permeabilities in heterologous systems. Upon stable expression in cultured tobacco (Nicotiana tabacum) Bright-Yellow 2 cells, OsHKT2;1 mediated Na⁺ uptake, but little Rb⁺ uptake, consistent with earlier studies and new findings presented here in oocytes. In contrast, OsHKT2;2 mediated Na⁺-K⁺ cotransport in plant cells such that extracellular K⁺ stimulated OsHKT2;2-mediated Na⁺ influx and vice versa. Furthermore, at millimolar Na⁺ concentrations, OsHKT2;2 mediated Na⁺ influx into plant cells without adding extracellular K⁺. This study shows that the Na⁺/K⁺ selectivities of these HKT transporters in plant cells coincide closely with the selectivities in oocytes and yeast. In addition, the presence of external K⁺ and Ca²⁺ down-regulated OsHKT2;1-mediated Na⁺ influx in two plant systems, Bright-Yellow 2 cells and intact rice roots, and also in Xenopus oocytes. Moreover, OsHKT transporter selectivities in plant cells are shown to depend on the imposed cationic conditions, supporting the model that HKT transporters are multi-ion pores.Intracellular Na⁺ and K⁺ homeostasis play vital roles in growth and development of higher plants (Clarkson and Hanson, 1980). Low cytosolic Na⁺ and high K⁺/Na⁺ ratios aid in maintaining an osmotic and biochemical equilibrium in plant cells. Na⁺ and K⁺ influx and efflux across membranes require the function of transmembrane Na⁺ and K⁺ transporters/channels. Several Na⁺-permeable transporters have been characterized in plants (Zhu, 2001; Horie and Schroeder, 2004; Apse and Blumwald, 2007). Na⁺/H⁺ antiporters mediate sequestration of Na⁺ into vacuoles under salt stress conditions in plants (Blumwald and Poole, 1985, 1987; Sze et al., 1999). Na⁺ (cation)/H⁺ antiporters are encoded by six AtNHX genes in Arabidopsis (Arabidopsis thaliana; Apse et al., 1999; Gaxiola et al., 1999; Yokoi et al., 2002; Aharon et al., 2003). A distinct Na⁺/H⁺ antiporter, Salt Overly Sensitive1, mediates Na⁺/H⁺ exchange at the plasma membrane and mediates cellular Na⁺ extrusion (Shi et al., 2000, 2002; Zhu, 2001; Ward et al., 2003). Electrophysiological analyses reveal that voltage-independent channels, also named nonselective cation channels, mediate Na⁺ influx into roots under high external Na⁺ concentrations (Amtmann et al., 1997; Tyerman et al., 1997; Buschmann et al., 2000; Davenport and Tester, 2000); however, the underlying genes remain unknown.Potassium is the most abundant cation in plants and an essential nutrient for plant growth. The Arabidopsis genome includes 13 genes encoding KUP/HAK/KT transporters (Quintero and Blatt, 1997; Santa-María et al., 1997; Fu and Luan, 1998; Kim et al., 1998), and 17 genes have been identified encoding this family of transporters in rice (Oryza sativa ‘Nipponbare’; Bañuelos et al., 2002). Several KUP/HAK/KT transporters have been characterized as mediating K⁺ uptake across the plasma membrane of plant cells (Rigas et al., 2001; Bañuelos et al., 2002; Gierth et al., 2005).Ionic balance, especially the Na⁺/K⁺ ratio, is a key factor of salt tolerance in plants (Niu et al., 1995; Maathuis and Amtmann, 1999; Shabala, 2000; Mäser et al., 2002a; Tester and Davenport, 2003; Horie et al., 2006; Apse and Blumwald, 2007; Chen et al., 2007; Gierth and Mäser, 2007). Salinity stress is a major problem for agricultural productivity of crops worldwide (Greenway and Munns, 1980; Zhu, 2001). The Arabidopsis AtHKT1;1 transporter plays a key role in salt tolerance of plants by mediating Na⁺ exclusion from leaves (Mäser et al., 2002a; Berthomieu et al., 2003; Gong et al., 2004; Sunarpi et al., 2005; Rus et al., 2006; Davenport et al., 2007; Horie et al., 2009). athkt1;1 mutations cause leaf chlorosis and elevated Na⁺ accumulation in leaves under salt stress conditions in Arabidopsis (Mäser et al., 2002a; Berthomieu et al., 2003; Gong et al., 2004; Sunarpi et al., 2005). AtHKT1;1 and its homolog in rice, OsHKT1;5 (SKC1), mediate leaf Na⁺ exclusion by removing Na⁺ from the xylem sap to protect plants from salinity stress (Ren et al., 2005; Sunarpi et al., 2005; Horie et al., 2006, 2009; Davenport et al., 2007).The land plant HKT gene family is divided into two classes based on their nucleic acid sequences and protein structures (Mäser et al., 2002b; Platten et al., 2006). Class 1 HKT transporters have a Ser residue at a selectivity filter position in the first pore loop, which is replaced by a Gly in all but one known class 2 HKT transporter (Horie et al., 2001; Mäser et al., 2002b; Garciadeblás et al., 2003). While the Arabidopsis genome includes only one HKT gene, AtHKT1;1 (Uozumi et al., 2000), seven full-length OsHKT genes were found in the japonica rice cv Nipponbare genome (Garciadeblás et al., 2003). Members of class 1 HKT transporters, AtHKT1;1 and SKC1/OsHKT1;5, have a relatively higher Na⁺-to-K⁺ selectivity in Xenopus laevis oocytes and yeast than class 2 HKT transporters (Uozumi et al., 2000; Horie et al., 2001; Mäser et al., 2002b; Ren et al., 2005). The first identified plant HKT transporter, TaHKT2;1 from wheat (Triticum aestivum), is a class 2 HKT transporter (Schachtman and Schroeder, 1994). TaHKT2;1 was found to mediate Na⁺-K⁺ cotransport and Na⁺ influx at high Na⁺ concentrations in heterologous expression systems (Rubio et al., 1995, 1999; Gassmann et al., 1996; Mäser et al., 2002b). Thus, class 1 HKT transporters have been characterized as Na⁺-preferring transporters with a smaller K⁺ permeability (Fairbairn et al., 2000; Uozumi et al., 2000; Su et al., 2003; Jabnoune et al., 2009), whereas class 2 HKT transporters function as Na⁺-K⁺ cotransporters or channels (Gassmann et al., 1996; Corratgé et al., 2007). In addition, at millimolar Na⁺ concentrations, class 2 HKT transporters were found to mediate Na⁺ influx, without adding external K⁺ in Xenopus oocytes and yeast (Rubio et al., 1995, 1999; Gassmann et al., 1996; Horie et al., 2001). However, the differential cation transport selectivities of the two types of HKT transporters have not yet been analyzed and compared in plant cells.A study of the barley (Hordeum vulgare) and wheat class 2 transporters has suggested that the transport properties of HvHKT2;1 and TaHKT2;1 expressed in yeast are variable, depending on the constructs from which the transporter is expressed, and have led to questioning of the K⁺ transport activity of HKT transporters characterized in Xenopus oocytes and yeast (Haro et al., 2005). It was further proposed that the 5′ translation initiation of HKT proteins in yeast at nonconventional (non-ATG) sites affects the transporter selectivities of HKT transporters (Haro et al., 2005), although direct evidence for this has not yet been presented. However, recent research has shown a K⁺ permeability of OsHKT2;1 but not of OsHKT1;1 and OsHKT1;3 in Xenopus oocytes. These three OsHKT transporters show overlapping and also distinctive expression patterns in rice (Jabnoune et al., 2009).The report of Haro et al. (2005) has opened a central question addressed in this study: are the Na⁺/K⁺ transport selectivities of plant HKT transporters characterized in heterologous systems of physiological relevance in plant cells, or do they exhibit strong differences in the cation transport selectivities in these nonplant versus plant systems? To address this question, we analyzed the Na⁺/K⁺ transport selectivities of the OsHKT2;1 and OsHKT2;2 transporters expressed in cultured tobacco (Nicotiana tabacum ‘Bright-Yellow 2’ [BY2]) cells. OsHKT2;1 and OsHKT2;2 are two highly homologous HKT transporters from indica rice cv Pokkali, sharing 91% amino acid and 93% cDNA sequence identity (Horie et al., 2001). OsHKT2;1 mediates mainly Na⁺ uptake, which correlates with the presence of a Ser residue in the first pore loop of OsHKT2;1 (Horie et al., 2001, 2007; Mäser et al., 2002b; Garciadeblás et al., 2003). In contrast, OsHKT2;2 mediates Na⁺-K⁺ cotransport in Xenopus oocytes and yeast (Horie et al., 2001). Furthermore, at millimolar Na⁺ concentrations, OsHKT2;2 mediates Na⁺ influx in the absence of added K⁺ (Horie et al., 2001). Recent research on oshkt2;1 loss-of-function mutant alleles has revealed that OsHKT2;1 from japonica rice mediates a large Na⁺ influx component into K⁺-starved roots, thus compensating for lack of K⁺ availability (Horie et al., 2007). But the detailed Na⁺/K⁺ selectivities of Gly-containing, predicted K⁺-transporting class 2 HKT transporters have not yet been analyzed in plant cells.Here, we have generated stable OsHKT2;1- and OsHKT2;2-expressing tobacco BY2 cell lines and characterized the cell lines by ion content measurements and tracer influx studies to directly analyze unidirectional fluxes (Epstein et al., 1963). These analyses showed that OsHKT2;1 exhibits Na⁺ uptake activity in plant BY2 cells in the absence of added K⁺, but little K⁺ (Rb⁺), influx activity. In contrast, OsHKT2;2 was found to function as a Na⁺-K⁺ cotransporter/channel in plant BY2 cells, showing K⁺-stimulated Na⁺ influx and Na⁺-stimulated K⁺ (Rb⁺) influx. The differential K⁺ selectivities of the two OsHKT2 transporters were consistently reproduced by voltage clamp experiments using Xenopus oocytes here, as reported previously (Horie et al., 2001). OsHKT2;2 was also found to mediate K⁺-independent Na⁺ influx at millimolar external Na⁺ concentrations. These findings demonstrate that the cation selectivities of OsHKT2;1 and OsHKT2;2 in plant cells are consistent with past findings obtained from heterologous expression analyses under similar ionic conditions (Horie et al., 2001; Garciadeblás et al., 2003; Tholema et al., 2005). Furthermore, the shift in OsHKT2;2 Na⁺-K⁺ selectivity depending on ionic editions is consistent with the model that HKT transporters/channels are multi-ion pores (Gassmann et al., 1996; Corratgé et al., 2007). Classical studies of ion channels have shown that ion channels, in which multiple ions can occupy the pore at the same time, can change their relative selectivities depending on the ionic conditions (Hille, 2001). Moreover, the presence of external K⁺ and Ca²⁺ was found here to down-regulate OsHKT2;1-mediated Na⁺ influx both in tobacco BY2 cells and in rice roots. The inhibitory effect of external K⁺ on OsHKT2;1-mediated Na⁺ influx into intact rice roots, however, showed a distinct difference in comparison with that of BY2 cells, which indicates a possible posttranslational regulation of OsHKT2;1 in K⁺-starved rice roots.     

Mitochondrial Ca2+ influx targets cardiolipin to disintegrate respiratory chain complex II for cell death induction

Massive Ca²⁺ influx into mitochondria is critically involved in cell death induction but it is unknown how this activates the organelle for cell destruction. Using multiple approaches including subcellular fractionation, FRET in intact cells, and in vitro reconstitutions, we show that mitochondrial Ca²⁺ influx prompts complex II of the respiratory chain to disintegrate, thereby releasing an enzymatically competent sub-complex that generates excessive reactive oxygen species (ROS) for cell death induction. This Ca²⁺-dependent dissociation of complex II is also observed in model membrane systems, but not when cardiolipin is replaced with a lipid devoid of Ca²⁺ binding. Cardiolipin is known to associate with complex II and upon Ca²⁺ binding coalesces into separate homotypic clusters. When complex II is deprived of this lipid, it disintegrates for ROS formation and cell death. Our results reveal Ca²⁺ binding to cardiolipin for complex II disintegration as a pivotal step for oxidative stress and cell death induction.Cellular calcium ion (Ca²⁺) overload is known to be of fundamental importance in pathological cell death induction for instance during brain ischemia, ischemia-reperfusion of the heart, and excitotoxicity of neurons.¹ Upon entering the cytosol from the extracellular space, Ca²⁺ ions accumulate in mitochondria at very high levels. An alternative route into mitochondria, observed during many scenarios of cell death, as well as when therapeutically induced by anticancer agents, is through Ca²⁺ release from the ER. After crossing the ER-mitochondrial junction, the ion is taken up by the mitochondrial calcium uniporter.^{2, 3} The close apposition of the two organelles ensures that a very high Ca²⁺ concentration can be reached in mitochondria.⁴ The direct target of mitochondrial Ca²⁺ influx for cell death induction, however, is unknown.Cells deficient in complex II of the respiratory chain become resistant to many cell death signals.⁵ The ability of this complex to produce deleterious amounts of reactive oxygen species (ROS) has been recognized.^{6, 7} Initial in vitro experiments using blue native gels indicated that during cell death, the sub-complex SDHA/SDHB, which remains enzymatically active,⁸ is specifically released from the membrane-anchoring SDHC and SDHD complex II subunits.⁹ It can then remove electrons from the substrate succinate and transfer them to molecular oxygen to generate ROS for cell death induction.^{5, 9}The principal lipid in the inner mitochondrial membrane that harbors the components of the respiratory chain, including complex II, is the diphosphatidylglycerol cardiolipin. This lipid is known to be involved in cell death, although its effects have been connected mostly with cellular sites different from its most prominent residence.^{10, 11, 12}In this study, we investigated whether excessive Ca²⁺ influx into mitochondria can affect on the integrity of complex II and activate this complex for cell death.     

TRPM2 channel deficiency prevents delayed cytosolic Zn2+ accumulation and CA1 pyramidal neuronal death after transient global ischemia

Transient ischemia is a leading cause of cognitive dysfunction. Postischemic ROS generation and an increase in the cytosolic Zn²⁺ level ([Zn²⁺]_c) are critical in delayed CA1 pyramidal neuronal death, but the underlying mechanisms are not fully understood. Here we investigated the role of ROS-sensitive TRPM2 (transient receptor potential melastatin-related 2) channel. Using in vivo and in vitro models of ischemia–reperfusion, we showed that genetic knockout of TRPM2 strongly prohibited the delayed increase in the [Zn²⁺]_c, ROS generation, CA1 pyramidal neuronal death and postischemic memory impairment. Time-lapse imaging revealed that TRPM2 deficiency had no effect on the ischemia-induced increase in the [Zn²⁺]_c but abolished the cytosolic Zn²⁺ accumulation during reperfusion as well as ROS-elicited increases in the [Zn²⁺]_c. These results provide the first evidence to show a critical role for TRPM2 channel activation during reperfusion in the delayed increase in the [Zn²⁺]_c and CA1 pyramidal neuronal death and identify TRPM2 as a key molecule signaling ROS generation to postischemic brain injury.Transient ischemia is a major cause of chronic neurological disabilities including memory impairment and cognitive dysfunctions in stroke survivors.^{1, 2} The underlying mechanisms are complicated and multiple, and remain not fully understood.³ It is well documented in rodents, non-human primates and humans that pyramidal neurons in the CA1 region of the hippocampus are particularly vulnerable and these neurons are demised after transient ischemia, commonly referred to as the delayed neuronal death.⁴ Studies using in vitro and in vivo models of transient ischemia have demonstrated that an increase in the [Zn²⁺]_c or cytosolic Zn²⁺ accumulation is a critical factor.^{5, 6, 7, 8, 9, 10, 11} There is evidence supporting a role for ischemia-evoked release of vesicular Zn²⁺ at glutamatergic presynaptic terminals and subsequent entry into postsynaptic neurons via GluA2-lacking AMPA subtype glutamate receptors (AMPARs) to raise the [Zn²⁺]_c.^{12, 13, 14, 15, 16} Upon reperfusion, while glutamate release returns to the preischemia level,¹⁷ Zn²⁺ can activate diverse ROS-generating machineries to generate excessive ROS as oxygen becomes available, which in turn elicits further Zn²⁺ accumulation during reperfusion.^{18, 19} ROS generation and cytosolic Zn²⁺ accumulation have a critical role in driving delayed CA1 pyramidal neuronal death,^{7, 12, 20, 21, 22} but the molecular mechanisms underlying such a vicious positive feedback during reperfusion remain poorly understood.Transient receptor potential melastatin-related 2 (TRPM2) forms non-selective cationic channels; their sensitivity to activation by ROS via a mechanism generating the channel activator ADP-ribose (ADPR) confers diverse cell types including hippocampal neurons with susceptibility to ROS-induced cell death, and thus TRPM2 acts as an important signaling molecule mediating ROS-induced adversities such as neurodegeneration.^{23, 24, 25, 26} Emergent evidence indeed supports the involvement of TRPM2 in transient ischemia-induced CA1 pyramidal neuronal death.^{27, 28, 29, 30} This has been attributed to the modulation of NMDA receptor-mediated signaling; despite that ROS-induced activation of the TRPM2 channels results in no change in the excitability of neurons from the wild-type (WT) mice, TRPM2 deficiency appeared to favor prosurvival synaptic Glu2A expression and inhibit prodeath extrasynaptic GluN2B expression.³⁰ A recent study suggests that TRPM2 activation results in extracellular Zn²⁺ influx to elevate the [Zn²⁺]_c.³¹ The present study, using TRPM2-deficient mice in conjunction with in vivo and in vitro models of transient global ischemia, provides compelling evidence to show ROS-induced TRPM2 activation during reperfusion as a crucial mechanism determining the delayed cytosolic Zn²⁺ accumulation, CA1 neuronal death and postischemic memory impairment.     

Fine-Tuning of the Cytoplasmic Ca2+ Concentration Is Essential for Pollen Tube Growth

Pollen tube growth is crucial for the delivery of sperm cells to the ovule during flowering plant reproduction. Previous in vitro imaging of Lilium longiflorum and Nicotiana tabacum has shown that growing pollen tubes exhibit a tip-focused Ca²⁺ concentration ([Ca²⁺]) gradient and regular oscillations of the cytosolic [Ca²⁺] ([Ca²⁺]_cyt) in the tip region. Whether this [Ca²⁺] gradient and/or [Ca²⁺]_cyt oscillations are present as the tube grows through the stigma (in vivo condition), however, is still not clear. We monitored [Ca²⁺]_cyt dynamics in pollen tubes under various conditions using Arabidopsis (Arabidopsis thaliana) and N. tabacum expressing yellow cameleon 3.60, a fluorescent calcium indicator with a large dynamic range. The tip-focused [Ca²⁺]_cyt gradient was always observed in growing pollen tubes. Regular oscillations of the [Ca²⁺]_cyt, however, were rarely identified in Arabidopsis or N. tabacum pollen tubes grown under the in vivo condition or in those placed in germination medium just after they had grown through a style (semi-in vivo condition). On the other hand, regular oscillations were observed in vitro in both growing and nongrowing pollen tubes, although the oscillation amplitude was 5-fold greater in the nongrowing pollen tubes compared with growing pollen tubes. These results suggested that a submicromolar [Ca²⁺]_cyt in the tip region is essential for pollen tube growth, whereas a regular [Ca²⁺] oscillation is not. Next, we monitored [Ca²⁺] dynamics in the endoplasmic reticulum ([Ca²⁺]_ER) in relation to Arabidopsis pollen tube growth using yellow cameleon 4.60, which has a lower affinity for Ca²⁺ compared with yellow cameleon 3.60. The [Ca²⁺]_ER in pollen tubes grown under the semi-in vivo condition was between 100 and 500 μm. In addition, cyclopiazonic acid, an inhibitor of ER-type Ca²⁺-ATPases, inhibited growth and decreased the [Ca²⁺]_ER. Our observations suggest that the ER serves as one of the Ca²⁺ stores in the pollen tube and cyclopiazonic acid-sensitive Ca²⁺-ATPases in the ER are required for pollen tube growth.In many flowering plants, a pollen grain that lands on the top surface of a stigma will hydrate and germinate a pollen tube. Following germination, the pollen tube enters the style and grows through the wall of transmitting tract cells on the way to the ovary, where the tube emerges to release the sperm for double fertilization. Therefore, pollen tube growth is essential for reproduction in flowering plants.Since Brewbaker and Kwack (1963) revealed that Ca²⁺ is essential for in vitro pollen tube cultures, the relationship between the Ca²⁺ concentration ([Ca²⁺]) and pollen tube growth has been further examined under in vitro germination culture conditions. Ratiometric ion imaging using fluorescent dye has revealed that the apical domain of a pollen tube grown in vitro contains a tip-focused [Ca²⁺] gradient (Pierson et al., 1994, 1996; Cheung and Wu, 2008) and that the cytoplasmic [Ca²⁺] ([Ca²⁺]_cyt) in the tip region and the growth rate oscillate with the same periodicity (Pierson et al., 1996; Holdaway-Clarke et al., 1997; Messerli and Robinson, 1997). Therefore, oscillation of the [Ca²⁺]_cyt has been thought to correlate with pollen tube growth. It is not clear, however, whether regular [Ca²⁺]_cyt oscillations in the tip region occur in pollen tubes growing through stigmas and styles.The [Ca²⁺]_cyt is controlled temporally and spatially by transporters in the membranes of intracellular compartments and in the plasma membrane (Sze et al., 2000). Studies using a Ca²⁺-sensitive vibrating electrode revealed Ca²⁺ influx in the tip region of the pollen tube (Pierson et al., 1994; Holdaway-Clarke et al., 1997; Franklin-Tong et al., 2002). Stretch-activated Ca²⁺ channels have been found in the plasma membrane using patch-clamp electrophysiology (Kuhtreiber and Jaffe, 1990; Dutta and Robinson, 2004). Recently, CNGC18 was identified as a Ca²⁺-permeable channel in the plasma membrane that is essential for pollen tube growth (Frietsch et al., 2007). The intracellular compartments that store Ca²⁺ in the pollen tube and the relevant Ca²⁺ transporters, however, have yet to be identified.Yellow cameleons are genetically encoded Ca²⁺ indicators that were developed to monitor the [Ca²⁺] in living cells (Miyawaki et al., 1997). These indicators are chimeric proteins consisting of enhanced cyan fluorescent protein (ECFP), calmodulin (CaM), a glycylglycine linker, the CaM-binding domain of myosin light chain kinase (M13), and enhanced yellow fluorescent protein (EYFP). When the CaM domain binds Ca²⁺, the domain associates with the M13 peptide and induces fluorescence resonance energy transfer (FRET) between ECFP and EYFP. Several types of cameleons have been developed by tuning the CaM domain binding affinity for Ca²⁺. Yellow cameleon 2.1 (YC2.1) is a high-affinity indicator that has been used to monitor the [Ca²⁺]_cyt in Arabidopsis (Arabidopsis thaliana) guard cells (Allen et al., 1999, 2000, 2001), Lilium longiflorum and Nicotiana tabacum pollen tubes (Watahiki et al., 2004), and the root hair of Medicago truncatula (Miwa et al., 2006). YC3.1 is a low-affinity indicator that has been used to monitor the [Ca²⁺]_cyt during pollen germination and in papilla cells of Arabidopsis (Iwano et al., 2004).Recently, YC3.60 was developed as a new YC variant (Nagai et al., 2004), in which the acceptor fluorophore is a circularly permuted version of Venus rather than EYFP (Nagai et al., 2002). YC3.60 has a monophasic Ca²⁺ dependency with a dissociation constant (K_d) of 0.25 μm. Compared with YC3.1, YC3.60 is equally bright with a 5- to 6-fold larger dynamic range. Thus, YC3.60 results in a markedly enhanced signal-to-noise ratio, thereby enabling Ca²⁺ imaging experiments that were not possible with conventional YCs. On the other hand, YC4.60 was developed by mutating the Ca²⁺-binding loop of CaM in YC3.60. Because YC4.60 has a significantly lower Ca²⁺ affinity with a biphasic Ca²⁺ dependency (K_d: 58 nm and 14.4 μm), it allows changes in [Ca²⁺] dynamics to be detected against a high background [Ca²⁺] (Nagai et al., 2004).To examine whether the [Ca²⁺]_cyt oscillates in pollen tubes growing through a stigma after pollination (in vivo condition), in those placed in germination medium immediately after passing through a style (semi-in vivo condition), or in those grown in germination medium (in vitro condition), we generated transgenic Arabidopsis and N. tabacum lines expressing the YC3.60 gene in their pollen grains and monitored Ca²⁺ dynamics in the pollen tube tip. We also examined how inhibitors of pollen tube growth affect Ca²⁺ dynamics in pollen tubes growing under the semi-in vivo condition. To examine Ca²⁺ dynamics in the endoplasmic reticulum (ER), we generated transgenic Arabidopsis plants expressing YC4.60 in the pollen tube ER. The results are discussed in relation to the physiological relevance of [Ca²⁺] oscillations for pollen tube growth.     

A Signaling Pathway Linking Nitric Oxide Production to Heterotrimeric G Protein and Hydrogen Peroxide Regulates Extracellular Calmodulin Induction of Stomatal Closure in Arabidopsis

Extracellular calmodulin (ExtCaM) regulates stomatal movement by eliciting a cascade of intracellular signaling events including heterotrimeric G protein, hydrogen peroxide (H₂O₂), and Ca²⁺. However, the ExtCaM-mediated guard cell signaling pathway remains poorly understood. In this report, we show that Arabidopsis (Arabidopsis thaliana) NITRIC OXIDE ASSOCIATED1 (AtNOA1)-dependent nitric oxide (NO) accumulation plays a crucial role in ExtCaM-induced stomatal closure. ExtCaM triggered a significant increase in NO levels associated with stomatal closure in the wild type, but both effects were abolished in the Atnoa1 mutant. Furthermore, we found that ExtCaM-mediated NO generation is regulated by GPA1, the Gα-subunit of heterotrimeric G protein. The ExtCaM-dependent NO accumulation was nullified in gpa1 knockout mutants but enhanced by overexpression of a constitutively active form of GPA1 (cGα). In addition, cGα Atnoa1 and gpa1-2 Atnoa1 double mutants exhibited a similar response as did Atnoa1. The defect in gpa1 was rescued by overexpression of AtNOA1. Finally, we demonstrated that G protein activation of NO production depends on H₂O₂. Reduced H₂O₂ levels in guard cells blocked the stomatal response of cGα lines, whereas exogenously applied H₂O₂ rescued the defect in ExtCaM-mediated stomatal closure in gpa1 mutants. Moreover, the atrbohD/F mutant, which lacks the NADPH oxidase activity in guard cells, had impaired NO generation in response to ExtCaM, and H₂O₂-induced stomatal closure and NO accumulation were greatly impaired in Atnoa1. These findings have established a signaling pathway leading to ExtCaM-induced stomatal closure, which involves GPA1-dependent activation of H₂O₂ production and subsequent AtNOA1-dependent NO accumulation.Plant guard cells control opening and closure of the stomata in response to phytohormones (e.g. abscisic acid [ABA]) and various environmental signals such as light and temperature, thereby regulating gas exchange for photosynthesis and water status via transpiration (Schroeder et al., 2001). Cytosolic calcium ([Ca²⁺]_i) has been shown to be a key second messenger that changes in response to multiple stimuli in guard cells (McAinsh et al., 1995; Grabov and Blatt, 1998; Wood et al., 2000). A large proportion of Ca²⁺ is localized in extracellular space. It has been shown that external Ca²⁺ concentration ([Ca²⁺]_o) promotes stomatal closure and induces oscillation in [Ca²⁺]_i in guard cells (MacRobbie, 1992; McAinsh et al., 1995; Allen et al., 2001). However, how the guard cells perceive [Ca²⁺]_o concentration and convert [Ca²⁺]_o changes into [Ca²⁺]_i changes was not understood until a calcium-sensing receptor (CAS) in the plasma membrane of guard cells in Arabidopsis (Arabidopsis thaliana) was identified (Han et al., 2003). The external Ca²⁺ (Ca²⁺_o)-induced [Ca²⁺]_i increase is abolished in CAS antisense lines (Han et al., 2003). Both [Ca²⁺]_o and [Ca²⁺]_i show diurnal oscillation that is determined by stomatal conductance, whereas the amplitude of [Ca²⁺]_i oscillation is reduced in CAS antisense lines (Tang et al., 2007). The reduced amplitude of [Ca²⁺]_i diurnal oscillation in response to Ca²⁺_o treatment suggests the potential existence of other [Ca²⁺]_o sensor(s) that may transmit [Ca²⁺]_o information into the [Ca²⁺]_i response in coordination with CAS. Extracellular calmodulin (ExtCaM) could be such an additional [Ca²⁺]_o sensor.Calmodulin is a well-known Ca²⁺ sensor that is activated upon binding of Ca²⁺. It has been shown that calmodulin exists not only intracellularly but also extracellularly in many plant species (Biro et al., 1984; Sun et al., 1994, 1995; Cui et al., 2005). ExtCaM has been implicated in several important biological functions, such as the promotion of cell proliferation, pollen germination, and tube growth (Sun et al., 1994, 1995; Ma and Sun, 1997; Ma et al., 1999; Cui et al., 2005; Shang et al., 2005). ExtCaM is found in the cell wall of guard cells in Vicia faba and in the epidermis of Arabidopsis by immunogold labeling/electron microscopy and western-blot analyses, respectively, and the endogenous CaM in the extracellular space has been shown to regulate stomatal movements (Chen et al., 2003; Xiao et al., 2004). Under natural conditions, once the activity of ExtCaM has been inhibited by its membrane-impermeable antagonist W7-agrose or CaM antibody, stomatal opening under light is enhanced and stomatal closure in darkness is inhibited in V. faba and Arabidopsis (Chen et al., 2003; Xiao et al., 2004). [Ca²⁺]_i and cytosolic hydrogen peroxide (H₂O₂) changes, two events involved in ExtCaM-regulated stomatal movement (Chen et al., 2004), are likely regulated by light/darkness (Chen and Gallie, 2004; Tang et al., 2007), suggesting that ExtCaM plays an important physiological role in the regulation of stomatal diurnal rhythm. Calmodulin-binding proteins have been found in the protoplast of suspension-cultured Arabidopsis cells, supporting the idea that ExtCaM functions as a peptide-signaling molecule (Cui et al., 2005). Furthermore, ExtCaM triggers [Ca²⁺]_i elevation in guard cells of V. faba and Arabidopsis and in lily (Lilium daviddi) pollen (Chen et al., 2004; Xiao et al., 2004; Shang et al., 2005). These observations support the notion that ExtCaM could be a potential [Ca²⁺]_o sensor for external calcium, and this external calcium sensing could subsequently regulate the [Ca²⁺]_i level through a signaling cascade.It is interesting that ExtCaM and ABA induce some parallel changes in second messengers in guard cell signaling. Our previous studies show that ExtCaM induces [Ca²⁺]_i increase and H₂O₂ generation through the Gα-subunit (GPA1) of a heterotrimeric G protein, and increased H₂O₂ further elevates [Ca²⁺]_i (Chen et al., 2004). G protein, Ca²⁺, and H₂O₂ are well-known second messengers in ABA-induced guard cell signaling (McAinsh et al., 1995; Grabov and Blatt, 1998; Pei et al., 2000; Wang et al., 2001; Zhang et al., 2001; Liu et al., 2007). However, the signaling cascade triggered by ExtCaM in guard cells is poorly understood. New ABA signaling components in guard cells could provide a clue in the study of the molecular mechanism of ExtCaM guard cell signaling.Recently, nitric oxide (NO) has been shown to serve as an important signal molecule involved in many aspects of developmental processes, including floral transition, root growth, root gravitropism, adventitious root formation, xylogenesis, seed germination, and orientation of pollen tube growth (Beligni and Lamattina, 2000; Pagnussat et al., 2002; He et al., 2004; Prado et al., 2004; Gabaldón et al., 2005; Stohr and Stremlau, 2006). Increasing evidence points to a role for NO as an essential component in ABA signaling in guard cells (Garcia-Mata and Lamattina, 2001, 2002; Neill et al., 2002). It has been shown that nitrate reductase (NR) reduces nitrite to NO, and the nia1, nia2 NR-deficient mutant in Arabidopsis showed reduced ABA induction of stomatal closure (Desikan et al., 2002; Bright et al., 2006). Although animal nitric oxide synthase (NOS) activity has been detected in plants and inhibitors of mammalian NOS impair NO production in plants (Barroso et al., 1999; Corpas et al., 2001), the gene(s) encoding NOS in plants is still not clear. AtNOS1 in Arabidopsis was initially reported to encode a protein containing NOS activity (Guo et al., 2003). However, recent studies have raised critical questions regarding the nature of AtNOS1 and suggested that AtNOS1 appears not to encode a NOS (Crawford et al., 2006; Zemojtel et al., 2006). However, the originally described Atnos1 mutant is deficient in NO accumulation (Crawford et al., 2006). Consequently, AtNOS1 was renamed AtNOA1 (for NITRIC OXIDE ASSOCIATED1; Crawford et al., 2006). Therefore, the Atnoa1 mutant provides a useful tool for dissecting the function of NO in plants. At present, the molecules that regulate NO generation in ABA-mediated guard cell signaling are not clear. Evidence suggests that H₂O₂, a second messenger important for the regulation of many developmental processes and stomatal movement (Pei et al., 2000; Zhang et al., 2001; Coelho et al., 2002; Demidchik et al., 2003; Kwak et al., 2003), regulates NO generation in guard cells (Lum et al., 2002; He et al., 2005; Bright et al., 2006).Given the parallel signaling events induced by ABA and ExtCaM, we investigated whether NO is involved in the regulation of ExtCaM-induced stomatal closure in Arabidopsis and whether it is linked to G protein and H₂O₂, two key regulators of both ExtCaM and ABA regulation of stomatal movements. Using Arabidopsis mutants (e.g. GPA1 null mutants, the NO-producing mutant Atnoa1, and the guard cell H₂O₂ synthetic enzymatic mutant atrbohD/F) combined with pharmacological analysis, we present compelling evidence to establish a linear functional relationship between Gα, H₂O₂, and NO in ExtCaM guard cell signaling.     

NaCl-Induced Alternations of Cellular and Tissue Ion Fluxes in Roots of Salt-Resistant and Salt-Sensitive Poplar Species

Using the scanning ion-selective electrode technique, fluxes of H⁺, Na⁺, and Cl⁻ were investigated in roots and derived protoplasts of salt-tolerant Populus euphratica and salt-sensitive Populus popularis 35-44 (P. popularis). Compared to P. popularis, P. euphratica roots exhibited a higher capacity to extrude Na⁺ after a short-term exposure to 50 mm NaCl (24 h) and a long term in a saline environment of 100 mm NaCl (15 d). Root protoplasts, isolated from the long-term-stressed P. euphratica roots, had an enhanced Na⁺ efflux and a correspondingly increased H⁺ influx, especially at an acidic pH of 5.5. However, the NaCl-induced Na⁺/H⁺ exchange in root tissues and cells was inhibited by amiloride (a Na⁺/H⁺ antiporter inhibitor) or sodium orthovanadate (a plasma membrane H⁺-ATPase inhibitor). These results indicate that the Na⁺ extrusion in stressed P. euphratica roots is the result of an active Na⁺/H⁺ antiport across the plasma membrane. In comparison, the Na⁺/H⁺ antiport system in salt-stressed P. popularis roots was insufficient to exclude Na⁺ at both the tissue and cellular levels. Moreover, salt-treated P. euphratica roots retained a higher capacity for Cl⁻ exclusion than P. popularis, especially during a long term in high salinity. The pattern of NaCl-induced fluxes of H⁺, Na⁺, and Cl⁻ differs from that caused by isomotic mannitol in P. euphratica roots, suggesting that NaCl-induced alternations of root ion fluxes are mainly the result of ion-specific effects.Soil salinity causes increasingly agricultural and environmental problems on a worldwide scale, especially in arid areas. When plant roots are subjected to saline environments with high NaCl content, external Na⁺ and Cl⁻ establish a large electrochemical gradient favoring the passive entry of salt ions through a variety of cation and anion channels and/or transporters in the plasma membrane (PM; Blumwald et al., 2000; Hasegawa et al., 2000; White and Broadley, 2001; Roberts, 2006; Demidchik and Maathuis, 2007). The entry and accumulation of toxic ions lead to disruption of ion homeostasis and finally cause secondary stress, e.g. oxidative bursts (Zhu, 2001, 2003). Accordingly, the maintenance of low salt concentration in the cytosol is of great importance for salt adaptation of plants (Greenway and Munns, 1980; Munns and Tester, 2008).Active Na⁺ extrusion to the apoplast or external environment is essential for sustaining Na⁺ homeostasis in the cytosol (Blumwald et al., 2000; Tester and Davenport, 2003; Zhu, 2003; Apse and Blumwald, 2007). PM Na⁺/H⁺ antiporters have been widely considered to play a crucial role in active Na⁺ extrusion under saline conditions (Shi et al., 2000, 2002; Qiu et al., 2002; Martínez-Atienza et al., 2007). NaCl-induced activity of PM Na⁺/H⁺ antiporter has been reported in crop species, tomato (Solanum lycopersicum; Wilson and Shannon, 1995), Arabidopsis (Arabidopsis thaliana; Qiu et al., 2002, 2003), and rice (Oryza sativa; Martínez-Atienza et al., 2007). Furthermore, overexpression of the Na⁺/H⁺ antiporter gene AtSOS1 decreases the accumulation of Na⁺ in transgenic Arabidopsis under NaCl stress (Shi et al., 2003). These PM Na⁺/H⁺ antiporters depend on electrochemical H⁺ gradients, which are generated by PM H⁺-ATPase (Blumwald et al., 2000; Zhu, 2003). Using an ion-selective microelectrode, Shabala and a colleague suggested the involvement of PM H⁺-ATPase in the Na⁺/H⁺ antiport according to H⁺ kinetics on salt shock (Shabala, 2000; Shabala and Newman, 2000). Therefore, the NaCl-induced H⁺ pumping is fundamental to Na⁺/H⁺ exchange and salinity tolerance (Ayala et al., 1996; Vitart et al., 2001; Chen et al., 2007; Gévaudant et al., 2007). However, the active Na⁺/H⁺ antiport across PM and the contribution to salt exclusion have been rarely investigated in tree species.Munns and Tester (2008) claimed that Cl⁻ toxicity is more important than Na⁺ toxicity in some woody species, e.g. citrus. Similarly, we have noticed that the inability to restrict Cl⁻ uptake contributes to the NaCl-induced salt damage in salt-sensitive poplar (Populus spp.) species, in addition to toxicity of excess Na⁺ (Chen et al., 2001, 2002, 2003). The differences in Cl⁻ tolerance exhibited by plants are usually related to the ability to restrict Cl⁻ transport to the aerial part (Greenway and Munns, 1980; White and Broadley, 2001). Excluding Cl⁻ from the xylem seems to be an effective mechanism for lotus to cope with the interactive effect of salt and water logging (Teakle et al., 2007). An influx of Cl⁻, immediately after addition of NaCl, was observed in bean (Vicia faba) mesophyll tissue (Shabala, 2000). The Cl⁻ flux response to salt shock is helpful to reveal the rapid adjustments of plants to salinity. However, Cl⁻ fluxes in salt-adapted roots, which are necessary to clarify plant adaptations to long durations of salinity, have not been examined.Populus euphratica has been widely considered as a model plant to elucidate physiological and molecular mechanisms of salt tolerance in woody species (Chen et al., 2001, 2002, 2003; Gu et al., 2004; Ottow et al., 2005a, 2005b; Junghans et al., 2006; Wang et al., 2007, 2008; Wu et al., 2007; Zhang et al., 2007). Comparative studies have shown that salt-stressed P. euphratica seedlings accumulate less Na⁺ and Cl⁻ in root and shoot tissues than salt-sensitive poplar species (Chen et al., 2001, 2002). It is suggested that the greater capacity to exclude NaCl in P. euphratica is likely the result of salt uptake and transport restriction in roots (Chen et al., 2002, 2003). However, this needs further investigations, e.g. by electrophysiology, to clarify.In this study, we used a noninvasive ion flux technique to measure the tissue and cellular fluxes of H⁺, Na⁺, and Cl⁻ in roots of the salt-tolerant P. euphratica and salt-sensitive P. popularis 35-44. The aim was to compare the NaCl-induced alternations of ion fluxes in poplar species differing in salt tolerance. Furthermore, we examined the effects of pH, salt shock, and PM transport inhibitors on Na⁺ and H⁺ fluxes in root-derived protoplasts of the salt-tolerant species, P. euphratica, which exhibited an evident Na⁺ exclusion under saline conditions.     

Augmentation of NAD+ by NQO1 attenuates cisplatin-mediated hearing impairment

Cisplatin (cis-diaminedichloroplatinum-II) is an extensively used chemotherapeutic agent, and one of its most adverse effects is ototoxicity. A number of studies have demonstrated that these effects are related to oxidative stress and DNA damage. However, the precise mechanism underlying cisplatin-associated ototoxicity is still unclear. The cofactor nicotinamide adenine dinucleotide (NAD⁺) has emerged as a key regulator of cellular energy metabolism and homeostasis. Here, we demonstrate for the first time that, in cisplatin-mediated ototoxicity, the levels and activities of SIRT1 are suppressed by the reduction of intracellular NAD⁺ levels. We provide evidence that the decrease in SIRT1 activity and expression facilitated by increasing poly(ADP-ribose) transferase (PARP)-1 activation and microRNA-34a through p53 activation aggravates cisplatin-mediated ototoxicity. Moreover, we show that the induction of cellular NAD⁺ levels using β-lapachone (β-Lap), whose intracellular target is NQO1, prevents the toxic effects of cisplatin through the regulation of PARP-1 and SIRT1 activity. These results suggest that direct modulation of cellular NAD⁺ levels by pharmacological agents could be a promising therapeutic approach for protection from cisplatin-induced ototoxicity.Cisplatin (cis-diamminedichloroplatinum (II)) is a chemotherapeutic agent extensively used to treat a variety of solid tumors in the head and neck, bladder, lung, ovaries, testicles, and uterus.¹ However, progressive irreversible side effects of cisplatin, including nephrotoxicity and ototoxicity, greatly impair the patient''s quality of life and frequently result in the need to lower the dosage during treatment or discontinuation of the treatment. Cisplatin ototoxicity primarily occurs in the cochlea and is generally caused by apoptotic damage to the outer hair cells (OHCs), spiral ganglion cells, and the marginal cells of the stria vascularis. In recent years, studies have demonstrated that cisplatin ototoxicity is also closely related to the damage of cochlear tissue by increased production of reactive oxygen species (ROS) and accompanied by the depletion of antioxidant substances and increased lipid peroxidation.^{2, 3} ROSs, particularly the hydroxyl radical, have a critical role in cisplatin-induced p53 activation through DNA damage.⁴ Although it is not easy to differentiate the cause from the consequence, a positive feedback loop between inflammatory cytokines and oxidative stress that worsen the cochlear damage is considered as one of the major mechanisms that facilitate cisplatin-induced hearing impairment.⁵ Interestingly, p53 and NF-κB have been described as key mediators of cisplatin-induced toxicity because of their involvement in oxidative stress, DNA damage, and inflammation through a mutual feedback process of ‘cause and effect.''^{6, 7} In addition, activities of p53 and NF-κB could be regulated by post-translational modifications, including phosphorylation and acetylation. Recent studies have reported that acetylated p53 and NF-κB are correlated with cisplatin-induced toxicity. Furthermore, acetylation of p53 and NF-κB is critically involved in cisplatin-induced renal injury.^{8, 9}Cellular nicotinamide adenine dinucleotide (NAD⁺) and NADH levels have been shown to be important mediators of energy metabolism and cellular homeostasis.^{10, 11} As NAD⁺ acts as a cofactor for various enzymes, including sirtuins (SIRTs), poly(ADP-ribose) transferases (PARPs), and cyclic ADP (cADP)-ribose synthases,^{12, 13} the regulation of NAD⁺ level may have therapeutic benefits through its effect on NAD⁺-dependent enzymes. SIRTs, NAD⁺-dependent protein deacetylases, are present as seven homologs of Sir2 (SIRT1-7) that show differential subcellular localizations in mammals.¹¹ Among these, nuclear SIRT1 is activated under energy stress conditions, such as fasting, exercise, or low glucose availability. ¹⁴ SIRT1 has a key role in metabolism, development, stress response, neurogenesis, hormone responses, and apoptosis^{15, 16} by deacetylation of substrates, such as NF-κB, FOXO, p53, and histones.^{17, 18, 19}PARPs, the most abundant ADP-ribosyl transferases, also use NAD⁺ to generate large amounts of poly(ADP-ribose) (PAR), which facilitate the recruitment of DNA repair factors. In particular, PARP-1 is a DNA damage sensor that can be activated in response to DNA damage by various pathophysiological conditions, including oxidative stress and inflammatory injury. However, excessive hyperactivation of PARP-1 causes the depletion of intracellular NAD⁺ and ATP levels, which eventually leads to cell death.^{20, 21} PARP-1 activation is also known as one of the important pathogenic mechanisms in cisplatin-induced toxicity.^{22, 23}A cytosolic antioxidant flavoprotein NADH:quinone oxidoreductase 1 (NQO1) catalyzes the reduction of quinones to hydroquinones by utilizing NADH as an electron donor, which consequently increases intracellular NAD⁺ levels.^{24, 25} In addition, accumulation evidence suggests that NQO1 has a role in other biological activities, including anti-inflammatory processes, scavenging of superoxide anion radicals, and stabilization of p53 and other tumor suppressor proteins.^{26, 27, 28} Several substrates of NQO1 enzyme, including mitomycin C, RH1, AZQ, Coenzyme Q10, and idebenone, have been identified,^{29, 30} of which β-lapachone (3,4-dihydro-2,2-dimethyl-2H-naphtho[1,2-b]pyran-5,6-dione; β-Lap) is recently well studied as a substrate of NQO1.^{31, 32} β-Lap was first isolated from the bark of the lapacho tree and reported to inhibit tumor cell line growth.³³ However, recent reports indicate that the conversion of NADH to NAD⁺ by NQO1 and β-Lap has beneficial effects on several characteristics of metabolic syndrome, for example, prevention of health decline in aged mice, amelioration of obesity or hypertension, prevention of arterial restenosis, and protection against salt-induced renal injury.^{34, 35, 36, 37, 38} Furthermore, we recently have demonstrated that conversion of NADH to NAD+ by NQO1 and β-Lap suppresses cisplatin-induced acute kidney injury by downregulating potential damage mediators such as oxidative stress and inflammatory responses.⁹Although a link between NAD⁺-dependent molecular events and cellular metabolism is evident, it remains unclear whether modulation of NAD⁺ levels has an impact on cisplatin-induced hearing impairment. Therefore, herein we investigated the role of NAD⁺ metabolism on cisplatin-induced cochlear dysfunction, and the effect of increased levels of intracellular NAD⁺ facilitated by β-Lap on cisplatin-induced hearing impairment with a particular interest in NAD⁺-dependent enzymatic pathways including SIRTs and PARPs.     

Defective sarcoplasmic reticulum–mitochondria calcium exchange in aged mouse myocardium

Mitochondrial alterations are critically involved in increased vulnerability to disease during aging. We investigated the contribution of mitochondria–sarcoplasmic reticulum (SR) communication in cardiomyocyte functional alterations during aging. Heart function (echocardiography) and ATP/phosphocreatine (NMR spectroscopy) were preserved in hearts from old mice (>20 months) with respect to young mice (5–6 months). Mitochondrial membrane potential and resting O₂ consumption were similar in mitochondria from young and old hearts. However, maximal ADP-stimulated O₂ consumption was specifically reduced in interfibrillar mitochondria from aged hearts. Second generation proteomics disclosed an increased mitochondrial protein oxidation in advanced age. Because energy production and oxidative status are regulated by mitochondrial Ca²⁺, we investigated the effect of age on mitochondrial Ca²⁺ uptake. Although no age-dependent differences were found in Ca²⁺ uptake kinetics in isolated mitochondria, mitochondrial Ca²⁺ uptake secondary to SR Ca²⁺ release was significantly reduced in cardiomyocytes from old hearts, and this effect was associated with decreased NAD(P)H regeneration and increased mitochondrial ROS upon increased contractile activity. Immunofluorescence and proximity ligation assay identified the defective communication between mitochondrial voltage-dependent anion channel and SR ryanodine receptor (RyR) in cardiomyocytes from aged hearts associated with altered Ca²⁺ handling. Age-dependent alterations in SR Ca²⁺ transfer to mitochondria and in Ca²⁺ handling could be reproduced in cardiomyoctes from young hearts after interorganelle disruption with colchicine, at concentrations that had no effect in aged cardiomyocytes or isolated mitochondria. Thus, defective SR–mitochondria communication underlies inefficient interorganelle Ca²⁺ exchange that contributes to energy demand/supply mistmach and oxidative stress in the aged heart.Age is the main independent risk factor for cardiovascular morbidity and mortality.¹ It increases heart vulnerability to cardiac diseases as well as the severity of their clinical manifestations, and reduces the efficacy of cardioprotective interventions.² At the cellular level, some of the structural and functional age-dependent changes resemble those of failing cardiac myocytes.^{3, 4} Specifically, disturbed Ca²⁺ homeostasis and excitation–contraction coupling,⁵ as well as deficient mitochondrial energetics⁶ and excessive ROS production,⁷ have been consistently reported in senescent cardiomyocytes. These subcellular alterations likely contribute to the reduced adaptive capacity to stress (exercise, β-adrenergic stimulation) and increased vulnerability to disease of the aged hearts.In cardiac cells, electrochemical coupling and metabolic adaptations are based upon the coordination between sarcoplasmic reticulum (SR) and mitochondria tightly interconnected forming an interface to support local ionic exchange and signal transduction in a beat-to-beat basis.⁸ This privileged interorganelle communication facilitates mitochondrial ATP transport for SR Ca²⁺ cycling and ensures energy replenishment by reciprocal Ca²⁺ and ADP exchange. Ca²⁺ is taken up by mitochondria using a low-affinity uniporter whose activity is driven by the elevated Ca²⁺ concentration in the microenvironment present around ryanodine receptors (RyR).⁹ Indeed, the kinetics of mitochondrial Ca²⁺ uptake is more dependent on the concentration of Ca²⁺ at the SR–mitochondria contact points than on bulk cytosolic Ca²⁺ concentration.⁸ Mitochondrial Ca²⁺ uptake allows energy supply–demand matching through the activation of Krebs cycle dehydrogenases and electron transport chain activity, and at the same time it regulates the regeneration of Krebs-coupled antioxidative defenses (NAD(P)H).¹⁰Defective SR–mitochondria cross talk has been causally linked to the abnormal mitochondrial Ca²⁺ uptake in failing hearts and may underlie their increased oxidative stress.¹¹ Also, in diabetic cardiomyopathy, intracellular Ca²⁺ overload and depletion of energy stores appear to develop as a consequence of sequential SR–mitochondria dysfunction.¹² Atrial fibrillation has been associated with an increased fusion of mitochondria and a subsequent increased colocalization of giant mitochondria with SR, a subcellular remodeling process that contributes to the perpetuation of the arrhythmia.¹³ Because mitochondria are highly dynamic structures, some molecular links have been proposed to provide a stable physical interorganelle bridge^{14, 15} while others appear to facilitate direct tunneling of Ca²⁺ and other signaling mediators.¹⁶ In the present study, we hypothesized that aging may negatively impact on mitochondria–SR communication by mechanisms involving defective Ca²⁺ transmission, and we identified reduced physical interaction between RyR and mitochondrial voltage-dependent anion channel (VDAC) as the main responsible of this effect.     

Scaffolding protein Homer1a protects against NMDA-induced neuronal injury

Excessive N-methyl-D-aspartate receptor (NMDAR) activation and the resulting activation of neuronal nitric oxide synthase (nNOS) cause neuronal injury. Homer1b/c facilitates NMDAR-PSD95-nNOS complex interactions, and Homer1a is a negative competitor of Homer1b/c. We report that Homer1a was both upregulated by and protected against NMDA-induced neuronal injury in vitro and in vivo. The neuroprotective activity of Homer1a was associated with NMDA-induced Ca²⁺ influx, oxidative stress and the resultant downstream signaling activation. Additionally, we found that Homer1a functionally regulated NMDAR channel properties in neurons, but did not regulate recombinant NR1/NR2B receptors in HEK293 cells. Furthermore, we found that Homer1a detached the physical links among NR2B, PSD95 and nNOS and reduced the membrane distribution of NMDAR. NMDA-induced neuronal injury was more severe in Homer1a homozygous knockout mice (KO, Homer1a^−/−) when compared with NMDA-induced neuronal injury in wild-type mice (WT, Homer1a^+/+). Additionally, Homer1a overexpression in the cortex of Homer1a^−/− mice alleviated NMDA-induced neuronal injury. These findings suggest that Homer1a may be a key neuroprotective endogenous molecule that protects against NMDA-induced neuronal injury by disassembling NR2B-PSD95-nNOS complexes and reducing the membrane distribution of NMDARs.Glutamate (Glu) acts on glutamate receptors, such as the N-methyl-D-aspartate receptor (NMDAR), and leads to neuronal hyper-excitability and death in a dose-dependent manner.¹ NMDAR activation induces Ca²⁺ influx and specifically activates neuronal nitric oxide synthase (nNOS) and downstream signaling pathways.^{2, 3, 4} Ca²⁺ influx is involved in glutamate-induced apoptosis caused by the activation of apoptosis-related signaling pathways, mitochondrial dysfunction and ROS induction.^{3, 4} Additionally, nNOS has been reported to contribute to NMDA-induced excitotoxicity.^{5, 6} Considering that direct NMDAR inhibition has not yet demonstrated favorable efficacy in most clinic trails and further considering the remarkable role of nNOS in NMDA-induced neuronal death,⁷ measures that can effectively protect neurons from NMDA-induced neuronal injury are urgently needed and represent a worthwhile research goal.Homer proteins belong to the postsynaptic density (PSD) family and consist of two major groups: the short-form Homer proteins (Homer1a and Ania3) and the long-form Homer proteins (Homer1b/c, Homer2 and Homer3).⁸ Homer1b/c has a conserved N-terminal Ena/VASP homology 1 domain and binds to group I metabotropic glutamate receptors (mGluRs), inositol triphosphate receptors and Shank family proteins.^{9, 10, 11, 12} Homer1b/c regulates surface receptor expression,^{13, 14} clustering,¹⁵ transient receptor potential family channels and mGluRs coupled to ion channels.^{10, 16, 17, 18, 19} Additionally, because of its C-terminal coiled-coil (CC) domains, Homer1b/c can self-multimerize, form multiprotein complexes and facilitate signal transduction to downstream pathways. Homer1a, which lacks the CC domain, is believed to compete with constitutive Homer1b/c and disrupt the association of multiple Homer1b/c complexes.Notably, Homer1b/c can interact with the Glu-induced Ca²⁺ influx pathway by binding to Shank, a NMDAR complex adaptor protein (NMDAR-PSD95-GKAP-Shank-Homer1b/c).^{12, 20} Furthermore, Homer1a also interacts with Shank, NMDA, nNOS and other Homer1b/c target proteins. Homer1a has a negative regulatory role by physically replacing certain target proteins, and is involved in the regulation of a variety of cellular and molecular functions in neurological diseases.^{21, 22, 23, 24, 25} Nevertheless, the mechanisms of action and associations between Homer1a and NMDA-induced neuronal injury have not yet been studied. Here, we aimed to investigate the possible neuroprotective effects of Homer1a and explore the mechanisms underlying Homer1a activity in NMDA-induced neuronal injury.     

Reduced mitochondrial Ca2+ transients stimulate autophagy in human fibroblasts carrying the 13514A>G mutation of the ND5 subunit of NADH dehydrogenase

Mitochondrial disorders are a group of pathologies characterized by impairment of mitochondrial function mainly due to defects of the respiratory chain and consequent organellar energetics. This affects organs and tissues that require an efficient energy supply, such as brain and skeletal muscle. They are caused by mutations in both nuclear- and mitochondrial DNA (mtDNA)-encoded genes and their clinical manifestations show a great heterogeneity in terms of age of onset and severity, suggesting that patient-specific features are key determinants of the pathogenic process. In order to correlate the genetic defect to the clinical phenotype, we used a cell culture model consisting of fibroblasts derived from patients with different mutations in the mtDNA-encoded ND5 complex I subunit and with different severities of the illness. Interestingly, we found that cells from patients with the 13514A>G mutation, who manifested a relatively late onset and slower progression of the disease, display an increased autophagic flux when compared with fibroblasts from other patients or healthy donors. We characterized their mitochondrial phenotype by investigating organelle turnover, morphology, membrane potential and Ca²⁺ homeostasis, demonstrating that mitochondrial quality control through mitophagy is upregulated in 13514A>G cells. This is due to a specific downregulation of mitochondrial Ca²⁺ uptake that causes the stimulation of the autophagic machinery through the AMPK signaling axis. Genetic and pharmacological manipulation of mitochondrial Ca²⁺ homeostasis can revert this phenotype, but concurrently decreases cell viability. This indicates that the higher mitochondrial turnover in complex I deficient cells with this specific mutation is a pro-survival compensatory mechanism that could contribute to the mild clinical phenotype of this patient.Mitochondrial disorders include a wide range of pathological conditions characterized by defects in organelle homoeostasis and energy metabolism, in particular in the electron transport chain (ETC) complexes. They are mostly caused by mutations in nuclear- or mtDNA-encoded genes of the respiratory chain complexes leading to a variety of clinical manifestations, ranging from lesions in specific tissues, such as in Leber''s hereditary optic neuropathy, to complex multisystem syndromes, such as myoclonic epilepsy with ragged-red fibers, Leigh syndrome or the mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes syndrome (MELAS).^{1, 2} Despite the detailed knowledge of the molecular defects in these diseases, their pathogenesis remains poorly understood. The heterogeneity of signs and symptoms depends on the diversity of the genetic background and on patient-specific compensatory mechanisms. Several studies investigated the consequences of nuclear DNA mutations on intracellular organelle physiology and Ca²⁺ homeostasis.^{3, 4} Here we analyzed a cohort of patients with mutations in the mtDNA-encoded ND5 subunit of NADH dehydrogenase in order to correlate the clinical phenotype with relevant intracellular parameters involved in mitochondrial physiology, such as the rate of autophagy and mitophagy fluxes, mitochondrial Ca²⁺ dynamics, mitochondrial membrane potential and their functional relationship.Mitochondrial Ca²⁺ is a key regulator of organelle physiology, and impairment of cation homeostasis is a general feature of many pathological conditions, including mitochondrial diseases.⁵ In addition, Ca²⁺ uptake in this organelle has recently been demonstrated to be a fundamental regulator of autophagy.^{6, 7} Autophagy is involved in physiological organelle turnover and in the removal of damaged or non-functional mitochondria by autophagy (called ‘mitophagy'')^{8, 9, 10, 11} and is critical for organelle quality control. Given the pivotal role of mitochondrial Ca²⁺ in the adaptation of adenosine triphosphate (ATP) production to cellular energy demand, the recent identification of the channel responsible for Ca²⁺ entry into the organelle, the mitochondrial Ca²⁺ uniporter (MCU), is instrumental for the understanding of the regulation of mitochondrial Ca²⁺ transport in both physiological and pathological conditions. MCU was identified in 2011,^{12, 13} and in the following years, molecular insight on its complex regulatory mechanism was obtained. The pore region is composed of MCU, its isoform MCUb¹⁴ and essential MCU regulator (EMRE).¹⁵ The channel is gated by the Ca²⁺-sensitive proteins mitochondrial Ca²⁺ uptake 1 (MICU1) and MICU2^{16, 17, 18, 19} and further regulated by the SLC25A23 protein.²⁰ As to its cellular function, mitochondrial Ca²⁺ has been shown to stimulate ATP production by positive regulation of three key dehydrogenases of the tricarboxylic acid cycle²¹ and of the ETC.²² In parallel, unregulated and sustained organelle Ca²⁺ overload can also lead to the opening of the mitochondrial permeability transition pore,^{23, 24} with consequent dissipation of mitochondrial membrane potential (ΔΨ_mt), release of caspase cofactors and activation of the apoptotic cascade.⁵ Despite the significant molecular understanding of all these cellular processes, their role in the pathogenesis of mitochondrial diseases is still poorly understood. Here we investigated the interplay of these pathways and the possibility of their contribution to determine the severity of the pathology in a cellular model consisting of fibroblasts from patients carrying mutations in the mitochondrial ND5 gene.     

Toso regulates differentiation and activation of inflammatory dendritic cells during persistence-prone virus infection

During virus infection and autoimmune disease, inflammatory dendritic cells (iDCs) differentiate from blood monocytes and infiltrate infected tissue. Following acute infection with hepatotropic viruses, iDCs are essential for re-stimulating virus-specific CD8⁺ T cells and therefore contribute to virus control. Here we used the lymphocytic choriomeningitis virus (LCMV) model system to identify novel signals, which influence the recruitment and activation of iDCs in the liver. We observed that intrinsic expression of Toso (Faim3, FcμR) influenced the differentiation and activation of iDCs in vivo and DCs in vitro. Lack of iDCs in Toso-deficient (Toso^–/–) mice reduced CD8⁺ T-cell function in the liver and resulted in virus persistence. Furthermore, Toso^–/– DCs failed to induce autoimmune diabetes in the rat insulin promoter-glycoprotein (RIP-GP) autoimmune diabetes model. In conclusion, we found that Toso has an essential role in the differentiation and maturation of iDCs, a process that is required for the control of persistence-prone virus infection.More than 500 million people worldwide suffer from chronic infections with hepatitis B or hepatitis C viruses.¹ Although both viruses are poorly cytopathic, persistence of either virus can lead to chronic liver inflammation and potentially cause liversteatosis, liver cirrhosis, end-stage liver failure or hepatocellular carcinoma. Virus-specific CD8⁺ T cells are a major determinant governing the outcome of viral hepatitis due to their antiviral activity against virus-infected hepatocytes.^{2, 3, 4, 5} However, during prolonged infection, virus-specific CD8⁺ T cells are exhausted, resulting in their loss of function and consequently virus persistence.^{1, 6} Regulators influencing CD8⁺ T-cell function during chronic virus infection still remain ill defined.Inflammatory dendritic cells (iDCs) can develop from a subset of monocytes recruited to the site of inflammation.^{7, 8} This monocyte subset is characterized by the expression of CD115⁺/Ly6C^hi/CCR2⁺.⁷ iDCs express CD11c, CD11b, and Ly6C.^{9, 10, 11} IDCs that exhibit tumor necrosis factor (TNF)-α production and inducible nitric oxide synthase (iNOS) were named TNF-α and iNOS producing DCs (Tip-DCs). iDCs contribute to the elimination of pathogens following bacterial infection.^{12, 13, 14} During infection with influenza virus, iDCs enhance CD8⁺ T-cell immunopathology, but have limited impact on viral replication.^{11, 15} According to recent observations, chronic activation of toll-like receptor 9 leads to intrahepatic myeloid-cell aggregates (iMATE).¹⁶ These aggregates, which contain iDCs, are essential for T-cell activation and therefore participate in virus control.¹⁶ Co-stimulatory signals from either direct cell contact or from cytokines in combination with continued antigen contact in iMATEs lead to proliferation and activation of virus-specific T cells.¹⁶ These observations suggest that infiltration of professional antigen-presenting cells into target organs is important for the maintenance of strong antiviral cytotoxic CD8⁺ T-cell activity. Factors regulating iDC infiltration into the liver remain poorly understood.Toso is a membrane protein whose extracellular domain has homology to the immunoglobulin variable (IgV) domains. The cytoplasmic region has partial homology to the FAST kinase (Fas-activated serine/threonine kinase).¹⁷ Toso is expressed on B cells and activated T cells¹⁷ and is overexpressed in B-cell lymphomas.^{18, 19} Expression of Toso can influence survival of macrophages.²⁰ Originally, Toso was described as an inhibitor of FAS signaling.^{17, 21} More recently, a role of Toso in IgM binding and TNFR signaling was also demonstrated^{22, 23, 24} and consistently, Toso-deficient animals are protected from lipopolysaccharide (LPS)-induced septic shock.^{24, 25} Recently, we identified a role of Toso in the activation of granulocytes, monocytes, and DCs.^{26, 27, 28} During infection with Listeria, the expression of Toso regulated granulocyte function.^{26, 27} The role of Toso in the function of monocytes and other myeloid cells still remains to be further elucidated.In this study, we investigated the role of Toso during chronic viral infection by using the murine lymphocytic choriomeningitis virus (LCMV). We report that Toso promotes the differentiation and maturation of iDCs at virus-infected sites, which were essential for effector CD8⁺ T-cell function and in accelerating the control of the virus. We further tested the role of Toso in the rat insulin promoter-glycoprotein (RIP-GP) autoimmune diabetes model and found that Toso was required to trigger diabetes in RIP-GP mice. Taken together, we have identified an essential role of Toso in the differentiation and maturation of iDCs, which is essential for the control of persistence-prone virus infection and triggering of autoimmune disease.