Gankyrin drives malignant transformation of chronic liver damage-mediated fibrosis via the Rac1/JNK pathway

Hepatocarcinogenesis is a complex process involving chronic liver injury, inflammation, unregulated wound healing, subsequent fibrosis and carcinogenesis. To decipher the molecular mechanism underlying transition from chronic liver injury to dysplasia, we investigated the oncogenic role of gankyrin (PSMD10 or p28^GANK) during malignant transformation in a transgenic mouse model. Here, we find that gankyrin increased in patients with cirrhosis. In addition to more severe liver fibrosis and tumorigenesis after DEN plus CCl₄ treatment, hepatocyte-specific gankyrin-overexpressing mice (gankyrin^hep) exhibited malignant transformation from liver fibrosis to tumors even under single CCl₄ administration, whereas wild-type mice merely experienced fibrosis. Consistently, enhanced hepatic injury, severe inflammation and strengthened compensatory proliferation occurred in gankyrin^hep mice during CCl₄ performance. This correlated with augmented expressions of cell cycle-related genes and abnormal activation of Rac1/c-jun N-terminal kinase (JNK). Pharmacological inhibition of the Rac1/JNK pathway attenuated hepatic fibrosis and prevented CCl₄-induced carcinogenesis in gankyrin^hep mice. Together, these findings suggest that gankyrin promotes liver fibrosis/cirrhosis progression into hepatocarcinoma relying on a persistent liver injury and inflammatory microenvironment. Blockade of Rac1/JNK activation impeded gankyrin-mediated hepatocytic malignant transformation, indicating the combined inhibition of gankyrin and Rac1/JNK as a potential prevention mechanism for cirrhosis transition.Hepatocellular carcinoma (HCC) is the prototype of inflammation-associated cancer, as most patients with HCC have an established background of unresolved chronic liver disease and cirrhosis.¹ Major HCC risk factors include infection with hepatitis viruses, intake of aflatoxin-contaminated food, alcoholic liver disease, nonalcoholic steatohepatitis (NASH), chronic hepatic inflammation and cirrhosis.^{2, 3} Cirrhosis is the primary risk factor for developing HCC, accompanied by long periods of chronic liver disease.⁴ However, the molecular mechanisms of this malignant transformation remain elusive.Gankyrin was identified as an oncoprotein that frequently overexpressed in human liver cancers and increased in the earlier stage of liver carcinogenesis.^{5, 6} It controls phosphorylated Rb and p53 degradation,^{7, 8} promotes the expansion of tumor-initiating cells⁹ and accelerates HCC progression. In addition, it also has been shown to regulate NF-κB and AKT.^{10, 11} We recently found that, in a rat model of carcinogen-induced liver carcinogenesis, gankyrin elevated in the stage of cirrhosis.¹² However, it is still unknown how gankyrin promotes hepatocarcinogenesis in vivo.Here, we show increased gankyrin expression in patients with cirrhosis. We further used hepatocyte-specific gankyrin-overexpressing mice to study the role of gankyrin in hepatocarcinogenesis. Sustained gankyrin activation promotes DEN plus carbon tetrachloride (CCl₄)-induced HCC formation. Moreover, it aggravates CCl₄-mediated liver injury, hepatic fibrosis and ultimately leads to the development of cirrhosis and progression into HCC.     

Death receptor-independent FADD signalling triggers hepatitis and hepatocellular carcinoma in mice with liver parenchymal cell-specific NEMO knockout

Hepatocellular carcinoma (HCC) usually develops in the context of chronic hepatitis triggered by viruses or toxic substances causing hepatocyte death, inflammation and compensatory proliferation of liver cells. Death receptors of the TNFR superfamily regulate cell death and inflammation and are implicated in liver disease and cancer. Liver parenchymal cell-specific ablation of NEMO/IKKγ, a subunit of the IκB kinase (IKK) complex that is essential for the activation of canonical NF-κB signalling, sensitized hepatocytes to apoptosis and caused the spontaneous development of chronic hepatitis and HCC in mice. Here we show that hepatitis and HCC development in NEMO^LPC-KO mice is triggered by death receptor-independent FADD-mediated hepatocyte apoptosis. TNF deficiency in all cells or conditional LPC-specific ablation of TNFR1, Fas or TRAIL-R did not prevent hepatocyte apoptosis, hepatitis and HCC development in NEMO^LPC-KO mice. To address potential functional redundancies between death receptors we generated and analysed NEMO^LPC-KO mice with combined LPC-specific deficiency of TNFR1, Fas and TRAIL-R and found that also simultaneous lack of all three death receptors did not prevent hepatocyte apoptosis, chronic hepatitis and HCC development. However, LPC-specific combined deficiency in TNFR1, Fas and TRAIL-R protected the NEMO-deficient liver from LPS-induced liver failure, showing that different mechanisms trigger spontaneous and LPS-induced hepatocyte apoptosis in NEMO^LPC-KO mice. In addition, NK cell depletion did not prevent liver damage and hepatitis. Moreover, NEMO^LPC-KO mice crossed into a RAG-1-deficient genetic background-developed hepatitis and HCC. Collectively, these results show that the spontaneous development of hepatocyte apoptosis, chronic hepatitis and HCC in NEMO^LPC-KO mice occurs independently of death receptor signalling, NK cells and B and T lymphocytes, arguing against an immunological trigger as the critical stimulus driving hepatocarcinogenesis in this model.Liver cancer is one of the most common malignancies and the third leading cause of cancer-related deaths worldwide.^{1, 2} Liver cancer predominantly arises in the context of chronic inflammatory conditions, most notably in virus hepatitis (HBV and HCV).^{1, 2} Although infectious agents are the primary cause of liver cancer worldwide, the incidence in western countries is rising due to the increase in obesity and non-alcoholic steatohepatitis.³ The pathogenesis of hepatocellular carcinoma (HCC) is incompletely understood and it is plausible that the different underlying aetiologies determine a distinct context for liver carcinogenesis. However, the prevailing universal concept is that continuous liver parenchymal damage and hepatocyte cell death drive compensatory proliferation and within the context of a chronically inflamed liver tissue mutations and epigenetic changes accumulate eventually transforming hepatocytes into malignant cells. Therefore, understanding the tissue-intrinsic processes that determine cell death and chronic inflammation resulting in hepatocarcinogenesis is a critical need in order to design more effective therapeutic strategies.The nuclear factor κB (NF-κB) pathway is implicated in cancer development in particular in the context of chronic inflammation.^{4, 5} In relation to liver cancer, NF-κB signalling has been implicated in the pathogenesis of hepatitis, liver fibrosis, cirrhosis and HCC.^{6, 7} The IKK complex, composed of two catalytic subunits, IKK1/IKKα and IKK2/IKKβ, and a regulatory subunit termed NEMO/IKKγ, activates NF-κB by phosphorylating inhibitor of NF-κB (IκB) proteins targeting them for degradation by the proteasome and thus allowing the nuclear accumulation of NF-κB dimers.⁵ IKK2 is primarily responsible for targeting and degrading IκBα thus inducing canonical NF-κB activation, although the two kinases show some degree of functional redundancy in controlling canonical NF-κB signalling.^{5, 8} NEMO/IKKγ is indispensable for activation of canonical NF-κB signalling.^{9, 10, 11}NF-κB signalling was proposed to exhibit tumour promoter or tumour suppressor properties in different models of liver cancer. In the Mdr2^−/− mouse model of inflammation-driven liver carcinogenesis, NF-κB inhibition caused by transgenic IκBα super–repressor expression in hepatocytes inhibited HCC progression.¹² Moreover, hepatocyte-restricted ablation of IKK2 prevented hepatitis and liver tumorigenesis induced by overexpression of lymphotoxins α and β in hepatocytes.¹³ However, mice with hepatocyte-specific IKK2 ablation developed more tumours induced by a single injection of the chemical carcinogen diethylnitrosamine,¹⁴ revealing a tumour suppressor role of NF-κB in this context.Studies in mice lacking NEMO specifically in liver parenchymal cells (LPCs) further supported a tumour suppressor function of IKK/NF-κB signalling in liver cancer. NEMO^LPC-KO mice showed spontaneous hepatocyte apoptosis resulting in chronic steatohepatitis and the development of HCC by the age of 1 year.¹⁵ LPC-specific ablation of Fas-Associated with Death Domain (FADD or MORT1), an adapter protein essential for the recruitment of caspase-8 to the Death Inducing Signalling Complex and the induction of death receptor-mediated apoptosis,¹⁶ prevented both spontaneous and LPS-induced apoptosis of NEMO-deficient hepatocytes and the development of steatohepatitis.¹⁵ In addition, LPC-specific knockout of caspase-8 inhibited spontaneous hepatocyte apoptosis and HCC development in NEMO^LPC-KO mice, although it caused non-apoptotic hepatocyte death and cholestasis.¹⁷ Given the essential role of FADD and caspase-8 in mediating apoptosis downstream of death receptors,¹⁶ we hypothesized that death receptor-mediated apoptosis of NEMO-deficient hepatocytes drives the development of hepatitis and HCC in NEMO^LPC-KO mice. The three main death receptors of the TNF receptor superfamily that are capable of inducing caspase-8-mediated apoptosis are TNFR1, Fas/CD95 and TRAIL-R/DR5.¹⁶ To address the role of death receptor-induced apoptosis in triggering the spontaneous death of NEMO-deficient hepatocytes and the development of steatohepatitis and HCC, we generated and analysed NEMO^LPC-KO mice lacking TNFR1, Fas or TRAIL-R specifically in LPCs. Surprisingly, we found that LPC-specific knockout of each of the death receptors alone but also combined deficiency of TNFR1, Fas and TRAIL-R in LPCs did not prevent spontaneous hepatocyte apoptosis, hepatitis and HCC development in NEMO^LPC-KO mice. In addition, knockout of TNF in all cells also did not protect NEMO^LPC-KO mice from hepatocyte death, hepatitis and HCC. Collectively, these results demonstrate that TNFR1, Fas and TRAIL-R are not required for the development of chronic liver damage and HCC in NEMO^LPC-KO mice.     

A cellular screen identifies ponatinib and pazopanib as inhibitors of necroptosis

Necroptosis is a form of regulated necrotic cell death mediated by receptor-interacting serine/threonine-protein kinase 1 (RIPK1) and RIPK3. Necroptotic cell death contributes to the pathophysiology of several disorders involving tissue damage, including myocardial infarction, stroke and ischemia-reperfusion injury. However, no inhibitors of necroptosis are currently in clinical use. Here we performed a phenotypic screen for small-molecule inhibitors of tumor necrosis factor-alpha (TNF-α)-induced necroptosis in Fas-associated protein with death domain (FADD)-deficient Jurkat cells using a representative panel of Food and Drug Administration (FDA)-approved drugs. We identified two anti-cancer agents, ponatinib and pazopanib, as submicromolar inhibitors of necroptosis. Both compounds inhibited necroptotic cell death induced by various cell death receptor ligands in human cells, while not protecting from apoptosis. Ponatinib and pazopanib abrogated phosphorylation of mixed lineage kinase domain-like protein (MLKL) upon TNF-α-induced necroptosis, indicating that both agents target a component upstream of MLKL. An unbiased chemical proteomic approach determined the cellular target spectrum of ponatinib, revealing key members of the necroptosis signaling pathway. We validated RIPK1, RIPK3 and transforming growth factor-β-activated kinase 1 (TAK1) as novel, direct targets of ponatinib by using competitive binding, cellular thermal shift and recombinant kinase assays. Ponatinib inhibited both RIPK1 and RIPK3, while pazopanib preferentially targeted RIPK1. The identification of the FDA-approved drugs ponatinib and pazopanib as cellular inhibitors of necroptosis highlights them as potentially interesting for the treatment of pathologies caused or aggravated by necroptotic cell death.Programmed cell death has a crucial role in a variety of biological processes ranging from normal tissue development to diverse pathological conditions.^{1, 2} Necroptosis is a form of regulated cell death that has been shown to occur during pathogen infection or sterile injury-induced inflammation in conditions where apoptosis signaling is compromised.^{3, 4, 5, 6} Given that many viruses have developed strategies to circumvent apoptotic cell death, necroptosis constitutes an important, pro-inflammatory back-up mechanism that limits viral spread in vivo.^{7, 8, 9} In contrast, in the context of sterile inflammation, necroptotic cell death contributes to disease pathology, outlining potential benefits of therapeutic intervention.¹⁰ Necroptosis can be initiated by death receptors of the tumor necrosis factor (TNF) superfamily,¹¹ Toll-like receptor 3 (TLR3),¹² TLR4,¹³ DNA-dependent activator of IFN-regulatory factors¹⁴ or interferon receptors.¹⁵ Downstream signaling is subsequently conveyed via RIPK1¹⁶ or TIR-domain-containing adapter-inducing interferon-β,^{8, 17} and converges on RIPK3-mediated^{13, 18, 19, 20} activation of MLKL.²¹ Phosphorylated MLKL triggers membrane rupture,^{22, 23, 24, 25, 26} releasing pro-inflammatory cellular contents to the extracellular space.²⁷ Studies using the RIPK1 inhibitor necrostatin-1 (Nec-1) ²⁸ or RIPK3-deficient mice have established a role for necroptosis in the pathophysiology of pancreatitis,¹⁹ artherosclerosis,²⁹ retinal cell death,³⁰ ischemic organ damage and ischemia-reperfusion injury in both the kidney³¹ and the heart.³² Moreover, allografts from RIPK3-deficient mice are better protected from rejection, suggesting necroptosis inhibition as a therapeutic option to improve transplant outcome.³³ Besides Nec-1, several tool compounds inhibiting different pathway members have been described,^{12, 16, 21, 34, 35} however, no inhibitors of necroptosis are available for clinical use so far.^{2, 10} In this study we screened a library of FDA approved drugs for the precise purpose of identifying already existing and generally safe chemical agents that could be used as necroptosis inhibitors. We identified the two structurally distinct kinase inhibitors pazopanib and ponatinib as potent blockers of necroptosis targeting the key enzymes RIPK1/3.     

TRAF2 is a biologically important necroptosis suppressor

Tumor necrosis factor α (TNFα) triggers necroptotic cell death through an intracellular signaling complex containing receptor-interacting protein kinase (RIPK) 1 and RIPK3, called the necrosome. RIPK1 phosphorylates RIPK3, which phosphorylates the pseudokinase mixed lineage kinase-domain-like (MLKL)—driving its oligomerization and membrane-disrupting necroptotic activity. Here, we show that TNF receptor-associated factor 2 (TRAF2)—previously implicated in apoptosis suppression—also inhibits necroptotic signaling by TNFα. TRAF2 disruption in mouse fibroblasts augmented TNFα–driven necrosome formation and RIPK3-MLKL association, promoting necroptosis. TRAF2 constitutively associated with MLKL, whereas TNFα reversed this via cylindromatosis-dependent TRAF2 deubiquitination. Ectopic interaction of TRAF2 and MLKL required the C-terminal portion but not the N-terminal, RING, or CIM region of TRAF2. Induced TRAF2 knockout (KO) in adult mice caused rapid lethality, in conjunction with increased hepatic necrosome assembly. By contrast, TRAF2 KO on a RIPK3 KO background caused delayed mortality, in concert with elevated intestinal caspase-8 protein and activity. Combined injection of TNFR1-Fc, Fas-Fc and DR5-Fc decoys prevented death upon TRAF2 KO. However, Fas-Fc and DR5-Fc were ineffective, whereas TNFR1-Fc and interferon α receptor (IFNAR1)-Fc were partially protective against lethality upon combined TRAF2 and RIPK3 KO. These results identify TRAF2 as an important biological suppressor of necroptosis in vitro and in vivo.Apoptotic cell death is mediated by caspases and has distinct morphological features, including membrane blebbing, cell shrinkage and nuclear fragmentation.^{1, 2, 3, 4} In contrast, necroptotic cell death is caspase-independent and is characterized by loss of membrane integrity, cell swelling and implosion.^{1, 2, 5} Nevertheless, necroptosis is a highly regulated process, requiring activation of RIPK1 and RIPK3, which form the core necrosome complex.^{1, 2, 5} Necrosome assembly can be induced via specific death receptors or toll-like receptors, among other modules.^{6, 7, 8, 9} The activated necrosome engages MLKL by RIPK3-mediated phosphorylation.^{6, 10, 11} MLKL then oligomerizes and binds to membrane phospholipids, forming pores that cause necroptotic cell death.^{10, 12, 13, 14, 15} Unchecked necroptosis disrupts embryonic development in mice and contributes to several human diseases.^{7, 8, 16, 17, 18, 19, 20, 21, 22}The apoptotic mediators FADD, caspase-8 and cFLIP suppress necroptosis.^{19, 20, 21, 23, 24} Elimination of any of these genes in mice causes embryonic lethality, subverted by additional deletion of RIPK3 or MLKL.^{19, 20, 21, 25} Necroptosis is also regulated at the level of RIPK1. Whereas TNFα engagement of TNFR1 leads to K63-linked ubiquitination of RIPK1 by cellular inhibitor of apoptosis proteins (cIAPs) to promote nuclear factor (NF)-κB activation,²⁶ necroptosis requires suppression or reversal of this modification to allow RIPK1 autophosphorylation and consequent RIPK3 activation.^{2, 23, 27, 28} CYLD promotes necroptotic signaling by deubiquitinating RIPK1, augmenting its interaction with RIPK3.²⁹ Conversely, caspase-8-mediated CYLD cleavage inhibits necroptosis.²⁴TRAF2 recruits cIAPs to the TNFα-TNFR1 signaling complex, facilitating NF-κB activation.^{30, 31, 32, 33} TRAF2 also supports K48-linked ubiquitination and proteasomal degradation of death-receptor-activated caspase-8, curbing apoptosis.³⁴ TRAF2 KO mice display embryonic lethality; some survive through birth but have severe developmental and immune deficiencies and die prematurely.^{35, 36} Conditional TRAF2 KO leads to rapid intestinal inflammation and mortality.³⁷ Furthermore, hepatic TRAF2 depletion augments apoptosis activation via Fas/CD95.³⁴ TRAF2 attenuates necroptosis induction in vitro by the death ligands Apo2L/TRAIL and Fas/CD95L.³⁸ However, it remains unclear whether TRAF2 regulates TNFα-induced necroptosis—and if so—how. Our present findings reveal that TRAF2 inhibits TNFα necroptotic signaling. Furthermore, our results establish TRAF2 as a biologically important necroptosis suppressor in vitro and in vivo and provide initial insight into the mechanisms underlying this function.     

Activation of volume-sensitive outwardly rectifying chloride channel by ROS contributes to ER stress and cardiac contractile dysfunction: involvement of CHOP through Wnt

Endoplasmic reticulum (ER) stress occurring in stringent conditions is critically involved in cardiomyocytes apoptosis and cardiac contractile dysfunction (CCD). However, the molecular machinery that mediates cardiac ER stress and subsequent cell death remains to be fully deciphered, which will hopefully provide novel therapeutic targets for these disorders. Here, we establish tunicamycin-induced model of cardiomyocyte ER stress, which effectively mimicks pathological stimuli to trigger CCD. Tunicamycin activates volume-sensitive outward rectifying Cl⁻ currents. Blockade of the volume-sensitive outwardly rectifying (VSOR) Cl⁻ channel by 4,4''-diisothiocya-natostilbene-2,2''-disulfonic acid (DIDS), a non-selective Cl⁻ channel blocker, and 4-(2-butyl-6,7-dichlor-2-cyclopentyl-indan-1-on-5-yl) oxybutyric acid (DCPIB), a selective VSOR Cl⁻ channel blocker, improves cardiac contractility, which correlates with suppressed ER stress through inhibiting the canonical GRP78/eIF2α/ATF4 and XBP1 pathways, and promotes survival of cardiomyocytes by inverting tunicamycin-induced decrease of Wnt through the CHOP pathway. VSOR activation of tunicamycin-treated cardiomyocytes is attributed to increased intracellular levels of reactive oxygen species (ROS). Our study demonstrates a pivotal role of ROS/VSOR in mediating ER stress and functional impairment of cardiomyocytes via the CHOP-Wnt pathway, and suggests the therapeutic values of VSOR Cl⁻ channel blockers against ER stress-associated cardiac anomalies.The endoplasmic reticulum (ER) is characterized as an organelle that participates in the folding of membrane and secretory proteins.^1,2 Efficient functioning of the endoplasmic reticulum is important for cell function and survival. Perturbations of ER homeostasis by energy deprivation and glucose,³ viral infections⁴ and accumulation of misfolded and/or unfolded proteins² interfere with ER function, leading to a state of ER stress.^{5, 6, 7} A cohort of chemicals, for example, tunicamycin and thapsigargin, also trigger ER stress.^{8, 9, 10} Thapsigargin disrupts the calcium storage of ER by blocking calcium reuptake into the ER lumen, thus by depleting calcium from the organelle.¹¹ In particular, tunicamycin is a highly specific ER stress inducer by inhibiting N-linked glycosylation of protein, representing a well-documented method to artificially elicit unfolded protein response.⁸ In response to ER stress, ER chaperones such as glucose-regulated protein 78 kDa (GRP78) and glucose-regulated protein 94 kDa (GRP94) are upregulated to facilitate the recovery of unfolded or misfolded proteins.¹² ER stress may act as a defense mechanism against external insults; however, prolonged and/or severe ER stress may ultimately trigger apoptosis.⁸ The C/EBP homologous protein (CHOP) has been defined as a pivotal mediator of cell death signaling in ER stress.^{13, 14} Accumulating evidence has demonstrated that ER stress-induced cell death is an essential step in the pathogenesis of a wide variety of cardiovascular diseases such as ischemia reperfusion heart diseases,¹⁵ atherosclerosis,^{5, 16, 17, 18} myocardial infarction,¹⁹ hypertension^{20, 21} and heart failure.^{8, 22, 23} Inhibiting ER stress has great therapeutic values for cardiac anomalies. However, the precise mechanism involved in ER stress-induced cardiovascular diseases has not been well identified, which impedes the translation of our understanding of ER stress-induced cardiovascular anomalies into effective therapeutic strategies. Apoptosis induction requires persistent cell shrinkage, named apoptotic volume decrease (AVD).^{24, 25, 26, 27} It is an early prerequisite for the activation of caspases.²⁴ In various types of cells including cardiomyocytes, AVD process is accomplished by the activation of volume-sensitive outwardly rectifying (VSOR) Cl⁻ channel and is concomitant with the egress of water from the cells undergoing mitochondrion-initiated or death receptor-induced apoptosis.^{25, 28, 29, 30} Although inhibition of VSOR Cl⁻ channel by DIDS (4,4''-diisothiocyanatostilbene-2,2''-disulphonic acid) and DCPIB (4-(2-butyl-6,7- dichlor-2-cyclopentyl-indan-1-on-5-yl) oxybutyric acid) blocked AVD and rescued cardiomyocytes from mitochondrial and death receptor pathway-induced apoptosis,^{31, 32} it remains largely unknown concerning the role of VSOR Cl⁻ channel and how it is regulated in ER stress-induced apoptotic cardiomyocyte death.Emerging evidence indicates that Wnt signal pathways are found to be anti-apoptotic in the cardiovascular diseases,^{33, 34, 35} regulating crucial aspects of cardiovascular biology. However, up to now, its activity in ER stress-induced apoptosis and in the process of AVD in cardiomyocytes remains elusive.In the present study, we probed the role of VSOR Cl⁻ channel in ER stress-induced apoptosis of cardiomyocytes, which intimately correlates with cardiac contractile dysfunction (CCD). We hypothesized that VSOR Cl⁻ channel controls the process of AVD occurring concomitantly with ER stress-induced apoptosis of cardiomyocytes. To test this hypothesis, we investigated VSOR Cl⁻ currents in cardiomyocytes treated with the ER stress inducer tunicamycin. The pathophysiological role of VSOR Cl⁻ channel and the potential signaling mechanisms in the development of ER stress-induced apoptosis in CCD were also dissected.     

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.     

Distinct roles of RIP1–RIP3 hetero- and RIP3–RIP3 homo-interaction in mediating necroptosis

Necroptosis is mediated by a signaling complex called necrosome, containing receptor-interacting protein (RIP)1, RIP3, and mixed-lineage kinase domain-like (MLKL). It is known that RIP1 and RIP3 form heterodimeric filamentous scaffold in necrosomes through their RIP homotypic interaction motif (RHIM) domain-mediated oligomerization, but the signaling events based on this scaffold has not been fully addressed. By using inducible dimer systems we found that RIP1–RIP1 interaction is dispensable for necroptosis; RIP1–RIP3 interaction is required for necroptosis signaling, but there is no necroptosis if no additional RIP3 protein is recruited to the RIP1–RIP3 heterodimer, and the interaction with RIP1 promotes the RIP3 to recruit other RIP3; RIP3–RIP3 interaction is required for necroptosis and RIP3–RIP3 dimerization is sufficient to induce necroptosis; and RIP3 dimer-induced necroptosis requires MLKL. We further show that RIP3 oligomer is not more potent than RIP3 dimer in triggering necroptosis, suggesting that RIP3 homo-interaction in the complex, rather than whether RIP3 has formed homo polymer, is important for necroptosis. RIP3 dimerization leads to RIP3 intramolecule autophosphorylation, which is required for the recruitment of MLKL. Interestingly, phosphorylation of one of RIP3 in the dimer is sufficient to induce necroptosis. As RIP1–RIP3 heterodimer itself cannot induce necroptosis, the RIP1–RIP3 heterodimeric amyloid fibril is unlikely to directly propagate necroptosis. We propose that the signaling events after the RIP1–RIP3 amyloid complex assembly are the recruitment of free RIP3 by the RIP3 in the amyloid scaffold followed by autophosphorylation of RIP3 and subsequent recruitment of MLKL by RIP3 to execute necroptosis.Necroptosis is a type of programmed necrosis characterized by necrotic morphological changes, including cellular organelle swelling, cell membrane rupture,^{1, 2, 3} and dependence of receptor-interacting protein (RIP)1⁴ and RIP3.^{5, 6, 7} Physiological function of necroptosis has been illustrated in host defense,^{8, 9, 10, 11} inflammation,^{12, 13, 14, 15, 16} tissue injury,^{10, 17, 18} and development.^{19, 20, 21}Necroptosis can be induced by a number of different extracellular stimuli such as tumor necrosis factor (TNF). TNF stimulation leads to formation of TNF receptor 1 (TNFR1) signaling complex (named complex I), and complex II containing RIP1, TRADD, FAS-associated protein with a death domain (FADD), and caspase-8, of which the activation initiates apoptosis. If cells have high level of RIP3, RIP1 recruits RIP3 to form necrosome containing FADD,^{22, 23, 24} caspase-8, RIP1, and RIP3, and the cells undergo necroptosis.^{25, 26} Caspase-8 and FADD negatively regulates necroptosis,^{27, 28, 29, 30} because RIP1, RIP3, and CYLD are potential substrates of caspase-8.^{31, 32, 33, 34} Necrosome also suppresses apoptosis but the underlying mechanism has not been described yet. Mixed-lineage kinase domain-like (MLKL) is downstream of RIP3,^{35, 36} and phosphorylation of MLKL is required for necroptosis.^{37, 38, 39, 40, 41, 42}Apoptosis inducing complex (complex II) and necrosome are both supramolecular complexes.^{43, 44, 45} A recent study showed that RIP1 and RIP3 form amyloidal fibrils through their RIP homotypic interaction motif⁴⁶ (RHIM)-mediated polymerization, and suggested that amyloidal structure is essential for necroptosis signaling.⁴⁷ The RIP1–RIP3 heterodimeric amyloid complex is believed to function as a scaffold that brings signaling proteins into proximity to permit their activation. However, RIP1 and RIP3 also can each form fibrils on their own RHIM domains in vitro. It is unclear how the homo- and hetero-interactions are coordinated and organized on the amyloid scaffold to execute their functions in necroptosis. Here, we used inducible dimerization systems to study the roles of RIP1–RIP1, RIP1–RIP3, and RIP3–RIP3 interactions in necroptosis signaling. Our data suggested that it is the RIP1–RIP3 interaction in the RIP1–RIP3 heterodimeric amyloid complex that empowers to recruit other free RIP3; homodimerization of RIP3 triggers its autophosphorylation and only the phosphorylated RIP3 can recruit MLKL to execute necroptosis.     

Divergent effects of RIP1 or RIP3 blockade in murine models of acute liver injury

Necroptosis is a recently described Caspase 8-independent method of cell death that denotes organized cellular necrosis. The roles of RIP1 and RIP3 in mediating hepatocyte death from acute liver injury are incompletely defined. Effects of necroptosis blockade were studied by separately targeting RIP1 and RIP3 in diverse murine models of acute liver injury. Blockade of necroptosis had disparate effects on disease outcome depending on the precise etiology of liver injury and component of the necrosome targeted. In ConA-induced autoimmune hepatitis, RIP3 deletion was protective, whereas RIP1 inhibition exacerbated disease, accelerated animal death, and was associated with increased hepatocyte apoptosis. Conversely, in acetaminophen-mediated liver injury, blockade of either RIP1 or RIP3 was protective and was associated with lower NLRP3 inflammasome activation. Our work highlights the fact that diverse modes of acute liver injury have differing requirements for RIP1 and RIP3; moreover, within a single injury model, RIP1 and RIP3 blockade can have diametrically opposite effects on tissue damage, suggesting that interference with distinct components of the necrosome must be considered separately.The etiologies of acute liver injury are diverse and its overall public health burden is considerable. Liver injury from acetaminophen (APAP) overdose is the most common cause of death from over-the-counter drugs and is the leading cause of acute liver failure in the developed world.^{1, 2, 3} Hepatic dysfunction from autoimmune hepatitis has a prevalence of 10–20/100 000.^{4, 5} Other etiologies of acute liver failure include idiosyncratic reaction to medications such as tetracycline, severe viral or alcoholic hepatitis, acute fatty liver of pregnancy, and idiopathic causes. Clinical complications resulting from liver failure include hepatic encephalopathy, impaired protein synthesis, and coagulopathies. Moreover, there are no effective means to reverse liver failure once advanced disease sets in – regardless of etiology – and transplantation frequently remains the only option for survival.⁶Concanavalin-A (ConA) is a lectin derived from the jack-bean plant with a unique ability to induce hepatitis in a well-described murine model of acute hepatic injury. ConA stimulates mouse CD4⁺ T-cell subsets to mediate insult to hepatocytes. The resulting cytokine release can further lead to recruitment and activation of innate inflammatory mediators, which perpetuate an insidious cycle of inflammation and hepatocellular injury.^{7, 8, 9}APAP is a widely used analgesic and antipyretic. Although usually considered safe at therapeutic doses, at higher doses APAP causes acute liver failure characterized by centrilobular hepatic necrosis.^{1, 10} At therapeutic doses, >90% of APAP is metabolized by glucuronidation and sulphation and its metabolites are excreted via the renal system. Of the remaining APAP, roughly 2% is excreted intact in the urine, and approximately 8% is metabolized by the cytochrome P450 system to N-acetyl-p-benzo-quinone imine (NAPQI), which is highly reactive.^{11, 12} Hepatic glutathione (GSH) then induces the formation of a safely excretable APAP-protein adduct. However, at toxic doses of APAP, GSH becomes depleted and NAPQI is able to exert harmful effects by forming covalent bonds with mitochondrial proteins, inhibiting the Ca²⁺-Mg²⁺-ATPase and inducing mitochondrial dysfunction.^{1, 2} This disturbance leads to a decrease in ATP synthesis, disruption of cellular membrane, and eventually hepatocyte death.¹³Although GSH depletion and the resulting toxic metabolites are prerequisites for APAP hepatotoxicity, there is evidence that the severity of liver injury may depend on subsequent participation of innate immunity.^{10, 14, 15, 16} In particular, APAP-induced injury has been reported to be contingent on activation of the NLRP3 inflammasome via DAMPs released from injured hepatocytes. Inflammasome activation cleaves Caspase 1 inducing IL-1β release and galvanizing intrahepatic neutrophils and inflammatory monocytes, which exacerbate injury.¹⁷ However, alternate studies using transgenic mice suggest that NLRP3 inflammasome is largely dispensable for APAP toxicity.¹⁸ Thus the role of inflammasome activation in APAP toxicity is controversial and may be dependent on the precise experimental conditions or strain of mice employed.Apoptosis and necrosis are classically understood processes of cell death that denote either organized Caspase 8-dependent programmed cell death or non-programmed disorganized death, respectively. In contrast to necrosis, which leads to the release of DAMPs and sustains inflammation, apoptosis produces cell fragments called apoptotic bodies, which phagocytic cells are able to engulf before the contents of the cell can spill out onto the surrounding space and activate innate immunity. ‘Necroptosis'' is a recently described Caspase 8-independent method of cell death that denotes organized cellular necrosis. Necroptosis requires the co-activation of RIP1 and RIP3 kinases. Both in vitro and in vivo investigations have suggested that APAP can induce cellular demise via necrosis or Caspase 8-dependent apoptosis, which is determined, in part, by ATP availability from glycolysis.¹⁹ Zhang et al.²⁰ recently confirmed that RIP1 is necessary in APAP-induced necroptosis. Similarly, Takemoto et al.²¹ showed that RIP1 inhibition protects against reactive oxygen species (ROS)-induced hepatotoxicity in APAP-induced acute liver injury. Further, a recent report suggested that selective inhibition of RIP3 using the anticancer drug Dabrafenib alleviates APAP injury.²²In the ConA model of acute liver injury, experiments using apoptosis-resistant mice expressing mutant FADD revealed that ConA alone induced primarily necrotic cell death, whereas ConA combined with d-galactosamine induced apoptosis and necrotic cell death.²³ Zhou et al.²⁴ reported that Necrostatin-1 (Nec-1) prevents autoimmune hepatitis in mice via RIP1- and autophagy-related pathways. Another recent report investigated the role of RIP1, RIP3, and PARP-1 in murine autoimmune hepatitis. This study found that in cases where death of mouse hepatocytes is dependent on TRAIL and NKT cells, PARP-1 activity was positively correlated with liver injury and hepatitis was prevented both by RIP1 or PARP-1 inhibitors.²⁵ Our goal in the current study was to investigate, in parallel, the effects of RIP1 and RIP3 blockade in diverse models of acute liver injury. Our work suggests that modulating necroptosis may have divergent effects, depending on the etiology of hepatic injury and the specific component of the necrosome being targeted.     

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.     

Depletion of white adipocyte progenitors induces beige adipocyte differentiation and suppresses obesity development

Overgrowth of white adipose tissue (WAT) in obesity occurs as a result of adipocyte hypertrophy and hyperplasia. Expansion and renewal of adipocytes relies on proliferation and differentiation of white adipocyte progenitors (WAP); however, the requirement of WAP for obesity development has not been proven. Here, we investigate whether depletion of WAP can be used to prevent WAT expansion. We test this approach by using a hunter-killer peptide designed to induce apoptosis selectively in WAP. We show that targeted WAP cytoablation results in a long-term WAT growth suppression despite increased caloric intake in a mouse diet-induced obesity model. Our data indicate that WAP depletion results in a compensatory population of adipose tissue with beige adipocytes. Consistent with reported thermogenic capacity of beige adipose tissue, WAP-depleted mice display increased energy expenditure. We conclude that targeting of white adipocyte progenitors could be developed as a strategy to sustained modulation of WAT metabolic activity.Obesity, a medical condition predisposing to diabetes, cardiovascular diseases, cancer, and complicating other life-threatening diseases, is becoming an increasingly important social problem.^{1, 2, 3} Development of pharmacological approaches to reduction of body fat has remained a daunting task.⁴ Approved obesity treatments typically produce only moderate and temporary effects.^2,5 White adipocytes are the differentiated cells of white adipose tissue (WAT) that store triglycerides in lipid droplets.^6,7 In contrast, adipocytes of brown adipose tissue (BAT) dissipate excess energy through adaptive thermogenesis. Under certain conditions, white adipocytes can become partially replaced with brown-like ‘beige'' (‘brite'') adipocytes that simulate the thermogenic function of BAT adipocytes.^7,8 Obesity develops in the context of positive energy balance as a result of hypertrophy and hyperplasia of white adipocytes.⁹Expansion and renewal of the white adipocyte pool in WAT continues in adulthood.^10,11 This process is believed to rely on proliferation and self-renewal of mesenchymal precursor cells¹² that we term white adipocyte progenitors (WAPs). WAPs reside within the population of adipose stromal cells (ASCs)¹³ and are functionally similar to bone marrow mesenchymal stem cells (MSCs).^{14, 15, 16} ASCs can be isolated from the stromal/vascular fraction (SVF) of WAT based on negativity for hematopoietic (CD45) and endothelial (CD31) markers.^17,18 ASCs support vascularization as mural/adventitial cells secreting angiogenic factors^5,19 and, unlike bone marrow MSCs, express CD34.^19,20 WAPs have been identified within the ASC population based on expression of mesenchymal markers, such as platelet-derived growth factor receptor-β (PDGFRβ, aka CD140b) and pericyte markers.^17,18 Recently, a distinct ASC progenitor population capable of differentiating into both white and brown adipocytes has been identified in WAT based on PDGFRα (CD140a) expression and lack of PDGFRβ expression.^21,22 The physiological relevance of the two precursor populations residing in WAT has not been explored.We have previously established an approach to isolate peptide ligands binding to receptors selectively expressed on the surface of cell populations of interest.^{23, 24, 25, 26, 27} Such cell-targeted peptides can be used for targeted delivery of experimental therapeutic agents in vivo. A number of ‘hunter-killer'' peptides²⁸ composed of a cell-homing domain binding to a surface marker and of KLAKLAK₂ (sequence KLAKLAKKLAKLAK), a moiety inducing apoptosis upon receptor-mediated internalization, has been described by our group.^26,29 Such bimodal peptides have been used for depletion of malignant cells and organ-specific endothelial cells in preclinical animal models.^26,30,31 Recently, we isolated a cyclic peptide WAT7 (amino acid sequence CSWKYWFGEC) based on its specific binding to ASCs.²⁰ We identified Δ-decorin (ΔDCN), a proteolytic cleavage fragment of decorin, as the WAT7 receptor specifically expressed on the surface of CD34+PDGFRβ+CD31-CD45- WAPs and absent on MSCs in other organs.²⁰Here, we investigated whether WAPs are required for obesity development in adulthood. By designing a new hunter-killer peptide that directs KLAKLAK₂ to WAPs through WAT7/ΔDCN interaction, we depleted WAP in the mouse diet-induced obesity model. We demonstrate that WAP depletion suppresses WAT growth. We show that, in response to WAP deficiency, WAT becomes populated with beige adipocytes. Consistent with the reported thermogenic function of beige adipocytes,^32,33 the observed WAT remodeling is associated with increased energy expenditure. We identify a population of PDGFRα-positive, PDGFRβ-negative ASCs reported recently²² as a population surviving WAP depletion and responsible for WAT browning.     

Cerium oxide nanoparticles protect against Aβ-induced mitochondrial fragmentation and neuronal cell death

Evidence indicates that nitrosative stress and mitochondrial dysfunction participate in the pathogenesis of Alzheimer''s disease (AD). Amyloid beta (Aβ) and peroxynitrite induce mitochondrial fragmentation and neuronal cell death by abnormal activation of dynamin-related protein 1 (DRP1), a large GTPase that regulates mitochondrial fission. The exact mechanisms of mitochondrial fragmentation and DRP1 overactivation in AD remain unknown; however, DRP1 serine 616 (S616) phosphorylation is likely involved. Although it is clear that nitrosative stress caused by peroxynitrite has a role in AD, effective antioxidant therapies are lacking. Cerium oxide nanoparticles, or nanoceria, switch between their Ce³⁺ and Ce⁴⁺ states and are able to scavenge superoxide anions, hydrogen peroxide and peroxynitrite. Therefore, nanoceria might protect against neurodegeneration. Here we report that nanoceria are internalized by neurons and accumulate at the mitochondrial outer membrane and plasma membrane. Furthermore, nanoceria reduce levels of reactive nitrogen species and protein tyrosine nitration in neurons exposed to peroxynitrite. Importantly, nanoceria reduce endogenous peroxynitrite and Aβ-induced mitochondrial fragmentation, DRP1 S616 hyperphosphorylation and neuronal cell death.Nitric oxide (NO) is a neurotransmitter and neuromodulator required for learning and memory.¹ NO is generated by NO synthases, a group of enzymes that produce NO from L-arginine. In addition to its normal role in physiology, NO is implicated in pathophysiology. When overproduced, NO combines with superoxide anions (O₂·⁻), byproducts of aerobic metabolism and mitochondrial oxidative phosphorylation, to form peroxynitrite anions (ONOO⁻) that are highly reactive and neurotoxic. Accumulation of these reactive oxygen species (ROS) and reactive nitrogen species (RNS), known as oxidative and nitrosative stress, respectively, is a common feature of aging, neurodegeneration and Alzheimer''s disease (AD).¹Nitrosative stress caused by peroxynitrite has a critical role in the etiology and pathogenesis of AD.^{2, 3, 4, 5, 6, 7} Peroxynitrite is implicated in the formation of the two hallmarks of AD, Aβ aggregates and neurofibrillary tangles containing hyperphosphorylated Tau protein.^{1, 4, 7} In addition, peroxynitrite promotes the nitrotyrosination of presenilin 1, the catalytic subunit of the γ-secretase complex, which shifts production of Aβ to amyloid beta (Aβ)42 and increases the Aβ42/Aβ40 ratio, ultimately resulting in an increased propensity for aggregation and neurotoxicity.⁵ Furthermore, nitration of Aβ tyrosine 10 enhances its aggregation.⁶ Peroxynitrite can also modify enzymes, such as triosephosphate isomerase,⁴ and activate kinases, including Jun amino-terminal kinase and p38 mitogen-activated protein kinase, which enhance neuronal cell death.^{8, 9} Moreover, peroxynitrite can trigger the release of free metals such as Zn²⁺ from intracellular stores with consequent inhibition of mitochondrial function and enhancement of neuronal cell death.^{10, 11, 12} Finally, peroxynitrite can irreversibly inhibit complexes I and IV of the mitochondrial respiratory chain.^{11, 13}Because mitochondria have a critical role in neurons as energy producers to fuel vital processes such as synaptic transmission and axonal transport,¹⁴ and mitochondrial dysfunction is a well-documented and early event in AD,¹⁵ it is important to consider how peroxynitrite and nitrosative stress affect mitochondria. Although the ultimate cause of mitochondrial dysfunction in AD remains unclear, an imbalance in mitochondrial fission and fusion is one possibility.^{1, 14, 16, 17, 18} Notably, peroxynitrite, N-methyl D-aspartate (NMDA) receptor activation and Aβ can induce mitochondrial fragmentation by activating mitochondrial fission and/or inhibiting fusion.¹⁶ Mitochondrial fission and fusion is regulated by large GTPases of the dynamin family, including dynamin-related protein 1 (DRP1) that is required for mitochondrial division,¹⁹ and inhibition of mitochondrial division by overexpression of the GTPase-defective DRP1^K38A mutant provides protection against peroxynitrite-, NMDA- and Aβ-induced mitochondrial fragmentation and neuronal cell death.¹⁶The exact mechanism of peroxynitrite-induced mitochondrial fragmentation remains unclear. A recent report suggested that S-nitrosylation of DRP1 at cysteine 644 increases DRP1 activity and is the cause of peroxynitrite-induced mitochondrial fragmentation in AD;²⁰ however, the work remains controversial, suggesting that alternative pathways might be involved.²¹ For example, peroxynitrite also causes rapid DRP1 S616 phosphorylation that promotes its translocation to mitochondria and organelle division.^{21, 22} In mitotic cells, DRP1 S616 phosphorylation is mediated by Cdk1/cyclinB1 and synchronizes mitochondrial division with cell division.²³ Interestingly, DRP1 is S616 hyperphosphorylated in AD brains, suggesting that this event might contribute to mitochondrial fragmentation in the disease.^{21, 22} A recent report indicates that Cdk5/p35 is responsible for DRP1 S616 phosphorylation,²⁴ and notably aberrant Cdk5/p35/p25 signaling is associated with AD pathogenesis.²⁵ Thus, we explored here the possible role of DRP1 S616 hyperphosphorylation in Aβ- and peroxynitrite-mediated mitochondrial fragmentation.Under normal conditions, accumulated mitochondrial superoxide anions and hydrogen peroxide (H₂O₂) can be neutralized by superoxide dismutase (SOD) and catalase. Nitrosative stress in aging and AD might be explained by a loss of antioxidant enzymes. Previous studies suggest that expression of SOD subtypes is decreased in the human AD brain.^{26, 27} Furthermore, SOD1 deletion in a mouse model of AD increased the burden of amyloid plaques.²⁶ By contrast, overexpression of SOD2 in a mouse model of AD decreased the Aβ42/Aβ40 ratio and alleviated memory deficits.^{28, 29} There is currently a lack of antioxidants that can effectively quench superoxide anions, H₂O₂ or peroxynitrite and provide lasting effects. Cerium is a rare earth element and cerium oxide (CeO₂) nanoparticles, or nanoceria, shuttle between their 3+ or 4+ states. Oxidation of Ce⁴⁺ to Ce³⁺ causes oxygen vacancies and defects on the surface of the crystalline lattice structure of the nanoparticles, generating a cage for redox reactions to occur.³⁰ Accordingly, nanoceria mimic the catalytic activities of antioxidant enzymes, such as SOD^{31, 32} and catalase,³³ and are able to neutralize peroxynitrite.³⁴ Because of these antioxidant properties, we hypothesized that nanoceria could detoxify peroxynitrite and protect against Aβ-induced DRP1 S616 hyperphosphorylation, mitochondrial fragmentation and neuronal cell death.     

PARP1 activation/expression modulates regional-specific neuronal and glial responses to seizure in a hemodynamic-independent manner

Poly(ADP-ribose) polymerase-1 (PARP1) plays a regulatory role in apoptosis, necrosis and other cellular processes after injury. Status epilepticus (SE) induces neuronal and astroglial death that show regional-specific patterns in the rat hippocampus and piriform cortex (PC). Thus, we investigated whether PARP1 regulates the differential neuronal/glial responses to pilocarpine (PILO)-induced SE in the distinct brain regions. In the present study, both CA1 and CA3 neurons showed PARP1 hyperactivation-dependent neuronal death pathway, whereas PC neurons exhibited PARP1 degradation-mediated neurodegeneration following SE. PARP1 degradation was also observed in astrocytes within the molecular layer of the dentate gyrus. PARP1 induction was detected in CA1–3-reactive astrocytes, as well as in reactive microglia within the PC. Although PARP1 inhibitors attenuated CA1–3 neuronal death and reactive gliosis in the CA1 region, they deteriorated the astroglial death in the molecular layer of the dentate gyrus and in the stratum lucidum of the CA3 region. Ex vivo study showed the similar regional and cellular patterns of PARP1 activation/degradation. Taken together, our findings suggest that the cellular-specific PARP1 activation/degradation may distinctly involve regional-specific neuronal damage, astroglial death and reactive gliosis in response to SE independently of hemodynamics.Poly(ADP-ribose) polymerase-1 (PARP1) repairs single-stranded DNA (ssDNA) breaks following various injuries. As PARP1 utilizes NAD⁺ to form poly(ADP-ribose) polymers (PAR) during this process, extensive PARP1 activation results in energy failure, promoting necrotic cell death because of NAD⁺ depletion.^{1, 2, 3, 4, 5, 6} Furthermore, PARP1 is a useful hallmark of apoptosis because full-length PARP1 is cleaved by the apoptotic proteases, caspase-3 and -7, into p85 and p25 fragments during apoptosis.^{7, 8} In contrast, the degradation of full-length PARP1 protein without cleavage into apoptotic fragments is mediated by caspase-independent ubiquitylation that plays a regulatory role in apoptosis, necrosis and other PARP1-regulated cellular processes.^{9, 10, 11, 12} Therefore, it is likely that the distinct profiles of PARP1 (activation, cleavage or degradation) may involve the differential cellular responses following harmful stimuli.Status epilepticus (SE) is a medical emergency with significant mortality.¹³ SE is a continuous seizure activity involving severe and prolonged hypoxia that induces sustained neuronal damage, astroglial death and reactive astrogliosis.^{14, 15, 16, 17, 18, 19, 20, 21, 22, 23} In particular, astroglial responses show regional-specific patterns following SE. Briefly, astroglial death was observed in the molecular layer of the dentate gyrus and the piriform cortex (PC) before or after neuronal death. In contrast, reactive astrogliosis was detected in other regions of the hippocampus and cortex.^{19, 20, 21, 22, 23, 24, 25} Based on the properties of PARP1 responses to stimuli, it is likely that PARP1 may be one of the potential molecules to involve neuronal damage and regional-specific astroglial responses to SE. In order to address this hypothesis, we first investigated the characteristics of PARP1 responses to SE in the rat hippocampus and PC. We then examined whether PARP1 regulates the neuronal/glial responses to SE, and finally whether hemodynamics involves PARP1 responses to SE using ex vivo model.