Mitochondrial 2', 3'-cyclic nucleotide 3'-phosphodiesterase (CNP) interacts with mPTP modulators and functional complexes (I-V) coupled with release of apoptotic factors.

We previously reported that 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNP) is present in rat brain and liver mitochondria, in the outer membrane and mitoplasts. Substrates of CNP, 2',3'-cAMP and 2',3'-cNADP, were found to accelerate opening of mitochondrial permeability transition pore (mPTP). In purified non-synaptic mitochondria, CNP was observed to co-immunoprecipitate with main modulators of mPTP, i.e. VDAC, ANT, and cyclophilin D, as well as with tubulin and COX IV. Using Blue Native Electrophoresis, with following Western blot, CNP was revealed to associate with functional inner membrane mitochondrial complexes I-V. In Ca(2+) -overloaded mitochondria, association of CNP with complexes I-V was decreased. Cyclosporine A increased the association of CNP with complexes I and III, supporting the idea of the involvement of these complexes in mPTP function. 2',3'-cAMP enhanced CNP dissociation from complexes I, III, IV and V in Ca(2+)-overloaded mitochondria (i.e. when pore is opened). Association of CNP with complexes I, III, IV, and V was shown in mitochondria isolated from brain, liver and heart. Stimulation of the opening of the non-selective pore in mitochondria correlated with CNP release from mitochondria in parallel with release of cytochrome c, AIF and Endo G. In Ca(2+)-overloaded mitochondria, 2',3'-cAMP further accelerated the release of AIF, Endo G and CNP, but did not alter cytochrome c release. These results provide strong evidence that CNP, one of the possible regulators of mPTP complex, might be involved in the control of respiration and energy production in mitochondria. This reveals a new function of CNP outside the myelin structure.

Extracellular α-crystallin protects astrocytes from cell death through activation of MAPK, PI3K/Akt signaling pathway and blockade of ROS release from mitochondria.

α-Crystallin with two isoforms, αA-crystallin (HSPB4) and αB-crystallin (HSPB5), is found in eye lens, spleen, lung, kidney, cornea, skin, but also in brain. Several studies revealed roles of αA/αB-crystallin in regulating cell viability and protection in the central nervous system. We previously demonstrated that α-crystallin serves as an intracellular protectant in astrocytes. Compared to well-studied intracellular functions of α-crystallin, there is limited proof for the role of α-crystallin as extracellular protectant. In order to clarify protective effects of extracellular αA/αB-crystallin, we exposed astrocytes to the toxic agents, staurosporine or C2-ceramide, or serum-starvation in the presence of αA/αB-crystallin. Extracellular αA/αB-crystallin protected astrocytes from staurosporine- and C2-ceramide-induced cell death. In addition, extracellular αB-crystallin/HSPB5 effectively promoted astrocytes viability through phosphatidylinositol 3 kinase (PI3K)/protein kinase B (Akt)/mammalian target of rapamycin (mTOR) and extracellular signal-regulated kinase 1/2 (ERK1/2), p38 mitogen-activated protein kinases (p38) and c-Jun N-terminal kinases (JNK) signaling pathways under serum-deprivation. Furthermore, αB-crystallin/HSPB5 decreases the staurosporine-mediated cleavage of caspase 3 through PI3K/Akt signaling preventing apoptosis of astrocytes. Thus, the current study indicates that extracellular αA/αB-crystallin protects astrocytes exposed to various harmful stimuli. Furthermore, application of αB-crystallin/HSPB5 to isolated rat brain mitochondria inhibits ROS generation induced by complex III inhibition with Antimycin A.

In aging, the vulnerability of rat brain mitochondria is enhanced due to reduced level of 2',3'-cyclic nucleotide-3'-phosphodiesterase (CNP) and subsequently increased permeability transition in brain mitochondria in old animals.

Aging is accompanied by progressive dysfunction of mitochondria associated with a continuous decrease of their capacity to produce ATP. Mitochondria isolated from brain of aged animals show an increased mitochondrial permeability transition pore (mPTP) opening. We recently detected new regulators of mPTP function in brain mitochondria, the enzyme 2', 3'-cyclic nucleotide 3'-phosphodiesterase (CNP) and its substrates 2', 3'-cAMP and 2', 3'-cNADP, and the neuronal protein p42(IP4). Here, we compared parameters of mPTP opening in non-synaptic brain mitochondria isolated from young and old rats. In mitochondria from old rats (>18 months), mPTP opening occurred at a lower threshold of Ca(2+) concentration than in mitochondria from young rats (<3 months). mPTP opening in mitochondria from old rats was accelerated by 2', 3'-cAMP, which further lowered the threshold Ca(2+) concentration. In non-synaptic mitochondria from old rats, the CNP level was decreased by 34%. Lowering of the CNP level in non-synaptic mitochondria with aging was accompanied by decreased levels of voltage-dependent anion channel (VDAC; by 69%) and of p42(IP4) (by 59%). Thus, reduced levels of CNP in mitochondria could lead to a rise in the concentration of the mPTP promoter 2', 3'-cAMP. The level of CNP and p42(IP4) and, probably VDAC, might be essential for myelination and electrical activity of axons. We propose that in aging the reduction in the level of these proteins leads to mitochondrial dysfunction, in particular, to a decreased threshold Ca(2+) concentration to induce mPTP opening. This might represent initial steps of age-related mitochondrial dysfunction, resulting in myelin and axonal pathology.

The intracellular carboxyl tail of the PAR-2 receptor controls intracellular signaling and cell death.

The protease-activated receptors are a group of unique G protein-coupled receptors, including PAR-1, PAR-2, PAR-3 and PAR-4. PAR-2 is activated by multiple trypsin-like serine proteases, including trypsin, tryptase and coagulation proteases. The clusters of phosphorylation sites in the PAR-2 carboxyl tail are suggested to be important for the binding of adaptor proteins to initiate intracellular signaling to Ca(2+) and mitogen-activated protein kinases. To explore the functional role of PAR-2 carboxyl tail in controlling intracellular Ca(2+), ERK and AKT signaling, a series of truncated mutants containing different clusters of serines/threonines were generated and expressed in HEK293 cells. Firstly, we observed that lack of the complete C-terminus of PAR-2 in a mutated receptor gave a relatively low level of localization on the cell plasma membrane. Secondly, the shortened carboxyl tail containing 13 amino acids was sufficient for receptor internalization. Thirdly, the cells expressing truncation mutants showed deficits in their capacity to couple to intracellular Ca(2+) and ERK and AKT signaling upon trypsin challenge. In addition, HEK293 cells carrying different PAR-2 truncation mutants displayed decreased levels of cell survival after long-lasting trypsin stimulation. In summary, the PAR-2 carboxyl tail was found to control the receptor localization, internalization, intracellular Ca(2+) responses and signaling to ERK and AKT. The latter can be considered to be important for cell death control.

Functions of the neuron-specific protein ADAP1 (centaurin-α1) in neuronal differentiation and neurodegenerative diseases, with an overview of structural and biochemical properties of ADAP1.

Eukaryotic cells express numerous ArfGAPs (ADP-ribosylation factor GTPase-activating proteins). There is increasing knowledge about the function of the brain-specific protein ADAP1 [ArfGAP with dual pleckstrin homology (PH) domain] as well as about its biochemical properties. The ADAP subfamily, also designated centaurin-α, has an N-terminal ArfGAP domain followed by two PH domains. The mammalian ADAP subfamily consists of two identified isoforms, ADAP1 and ADAP2 (centaurin-α1 and -α2). ADAP1 is highly expressed in neurons. We highlight the functional roles of ADAP1 in neuronal differentiation and neurodegeneration. Because of interactions with different proteins and phosphoinositol-lipids, ADAP1 can function as a scaffolding protein in several signal transduction pathways. Firstly, ADAP1 mediates cytoskeletal crosstalk. This is indicated by multiple interactions of ADAP1 with components of the actin and microtubule cytoskeleton. Secondly, regulation of neuronal polarity formation and axon specification by ADAP1 is suggested by crystal structural data obtained for human ADAP1, and the complexes of ADAP1-Ins(1,3,4,5)P4 and/or the forkhead-associated domain of the kinesin KIF13B. These structures support the concept that a KIF13B-ADAP1 complex enhances the local accumulation of PtdIns(3,4,5)P3 at the tips of neurites, and thus favors neuronal polarity. Thirdly, recent evidence unravels a pathological role of ADAP1 because upregulation of ADAP1 by amyloid ß-peptide causes ADAP1-Ras-ERK-dependent translocation of Elk-1 to mitochondria. This impairs mitochondrial functions with subsequent synaptic dysfunction and exacerbates neurodegeneration, as in Alzheimer's disease.

Identification of phosphorylated form of 2', 3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) as 46 kDa phosphoprotein in brain non-synaptic mitochondria overloaded by calcium.

In our previous studies phosphorylation of several membrane-bound proteins in brain and liver mitochondria were found to be regulated by Ca(2+) as a second messenger. One of the proteins, the 46 kDa phosphoprotein was found to be highly phosphorylated when Ca(2+)-induced permeability transition pore (mPTP) was opened in rat brain mitochondria (RBM). In the present study the 46 kDa phosphoprotein was identified as 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) after purification by 2D diagonal electrophoresis following mass spectrometric analysis and Western blot probed with anti-CNP antibody. CNPase was discovered in immunoprecipitates of mitochondria, phosphorylated under both conditions (control and with opened mPTP). Status phosphorylation of CNPase was found to be higher in the inmmunoprecipiates of calcium-overloaded RBM. The phospohoserine and phosphotyrosine residues were detected in phosphorylated 46 kDa band (CNPase) as well as in CNPase immunoprecipitates indicating possible participation of tyrosine and serine protein kinases in phosphorylation of CNPase in mitochondria. The levels of phospo-Ser and phospho-Tyr were increased in RBM with mPTP opened. It was found that CNPase substrate, 2',3'-cAMP (5 µM) and, a non-competitive CNPase inhibitor, atractyloside (5 µM), were able to increase the level of CNPase phosphorylation in calcium-overloaded mitochondria, while CsA (mPTP blocker) was able to strong suppress the phosphorylation of the enzyme. Collectively, our results provide evidence that Ca(2+)-stimulated and mPTP-associated CNPase phosphorylation might be an important stage of mPTP regulation in mitochondria, revealing a new function of CNPase outside of myelin structure.

NF-κB-dependent and -independent pathways in the protective effects of activated protein C in hippocampal and cortical neurons at excitotoxicity.

The transcription factor NF-κB regulates the expression of multiple genes involved in inflammation, apoptotic cell death and cell survival. We previously demonstrated that activated protein C (APC), a serine protease of hemostasis with anticoagulant activity, protected cultured rat cortical and hippocampal neurons against glutamate-induced excitotoxicity, a model of ischemic stroke. We reported that APC suppressed the translocation of NF-κBp65/RelA into the nucleus of neurons. However, it is not known whether APC-induced protection of neurons against cell death occurs via regulation of NF-κB activation or NF-κB-independent p53 expression. It is also unclear whether cleaved caspase-3 and caspase-independent AIF and Bax/Bcl-2 expression are involved at excitotoxicity. To elucidate the NF-κB dependent and -independent mechanisms in the APC-mediated cell survival, we analyzed in cortical and hippocampal neurons the effects of helenalin, a specific inhibitor of NF-κB activity, and APC on neuronal cell death and on the level of nuclear AIF, p53, caspase-3 and the apoptotic index (Bax/Bcl-2 ratio). We could demonstrate that helenalin (5 µM), like APC (1 nM), protects cultured neurons from glutamate-induced excitotoxicity. Both APC and helenalin inhibit AIF release from mitochondria and its translocation into the nucleus. They decrease the apoptotic index in neurons at excitotoxicity. However, APC, but not helenalin, reduced the glutamate-induced activation of caspase-3. Incubation of neurons with APC blocked the glutamate-induced increase in the nuclear level of p53 via NF-κB-independent pathway. Our findings demonstrate that, in the protective effect of APC in neurons at excitotoxicity, the NF-κB pathway is an important, but not the only pathway, and is significantly connected with neuronal survival at excitotoxicity.

Decreased expression of nardilysin in SH-SY5Y cells under ethanol stress and reduced density of nardilysin-expressing neurons in brains of alcoholics.

There is evidence for a genetic link between the metalloendopeptidase nardilysin and alcohol dependence, but the functional implication of the enzyme in alcoholism is unknown. Interestingly, some of the enzyme's substrates and interaction partners are altered in neural and non-neural tissues under the influence of ethanol consumption. To learn more about putative roles of nardilysin in alcohol dependence we studied the expression of the enzyme protein in human neuroblastoma cells under chronic ethanol exposure as well as in four brain regions of alcoholics and matched controls. Cultured SH-SY5Y cells were exposed for 96 h to two different concentrations of ethanol (50 and 200 mM). Nardilysin expression was determined using Western blotting with densitometric analysis. Furthermore, we morphometrically studied the cellular expression of nardilysin in postmortem brains of eight chronic alcoholics and nine controls by counting the number of nardilysin-immunopositive neurons in left frontal limbic area, Nuc. basalis of Meynert, paraventricular and supraoptic hypothalamic nuclei and calculating numerical cell densities. Nardilysin expression was significantly reduced after 96 h of SH-SY5Y cells exposure to 200 mM ethanol. In human brains nardilysin protein was localized to multiple neurons. In heavy drinkers there was a significantly reduced density of nardilysin immunoreactive neurons in Nuc. basalis of Meynert, paraventricular, and supraoptic nuclei. The alcohol-dependent reduction of nardilysin in cell culture and nervous tissue points to an implication of the enzyme in the pathophysiology of alcoholism.

Tubulin potentiates the interaction of the metalloendopeptidase nardilysin with the neuronal scaffold protein p42IP4/centaurin-α1 (ADAP1).

We found colocalization of the neuronal protein p42(IP4) (centaurin-α1; ArfGAP with dual pleckstrin homology domain [ADAP1]), the metalloendopeptidase nardilysin (NRD; involved in axonal maturation and myelination) and tubulin in the cytosol and at the plasma membrane of SH-SY5Y neuroblastoma cells. To examine the importance of tubulin for the interaction of NRD with p42(IP4), we treated cells with nocodazole, which interferes with tubulin polymerization. Nocodazole did not affect the colocalization of p42(IP4) and tubulin but caused a clear redistribution of the proteins in cells, so that the colocalization of p42(IP4), tubulin and NRD was visible exclusively in multiple foci. To reveal the mechanism of the interaction between NRD, p42(IP4) and tubulin observed in neuronal cells, we performed Far-Western blotting, a technique that directly detects protein-protein interactions on Western blots. This technique demonstrated that tubulin enhanced the binding of NRD to functionally renatured p42(IP4). The mutation of a highly conserved cysteine residue in NRD to alanine abolished the potentiation by tubulin. NRD lacking the characteristic acidic domain was able to bind p42(IP4) but addition of tubulin did not significantly potentiate the binding of this deletion mutant to p42(IP4). A function-abolishing mutation of the Zn(2+)-binding motif of NRD did not affect the potentiation by tubulin. Thus, the capacity of tubulin to enhance the interaction between p42(IP4) and NRD together with the known interaction of p42(IP4) with F-actin support the novel notion that p42(IP4) plays a possible role as a linker between the two networks, actin and tubulin, in neural cells.

Retinoic acid-induced upregulation of the metalloendopeptidase nardilysin is accelerated by co-expression of the brain-specific protein p42(IP4) (centaurin α 1; ADAP1) in neuroblastoma cells.

The mainly neuronally expressed protein p42(IP4) (centaurin α1; ADAP1), which interacts with the metalloendopeptidase nardilysin (NRD) was found to be localized in neuritic plaques in Alzheimer disease (AD) brains. NRD was shown to enhance the cleavage of the amyloid precursor protein (APP) by α-secretases, thereby increasing the release of neuroprotective sAPPα. We here investigated in vitro the biochemical interaction of p42(IP4) and NRD and studied the physiological interaction in SH-SY5Y cells. NRD is a member of the M16 family of metalloendopeptidases. Some members of this M16 family act bi-functionally, as protease and as non-enzymatic scaffold protein. Here, we show that p42(IP4) enhances the enzymatic activity of NRD 3-4 times. However, p42(IP4) is not a substrate for NRD. Furthermore, we report that differentiation of SH-SY5Y cells by stimulation with 10µM retinoic acid (RA) results in upregulation of NRD protein levels, with a 6-fold rise after 15 days. NRD is expressed in the neurites of RA-stimulated SH-SY5Y cells, and localized in vesicular structures. Since p42(IP4) is not expressed in untreated SH-SY5Y cells, we could use this cell system as a model to find out, whether there is a functional interaction. Interestingly, SH-SY5Y cells, which we stably transfected with GFP-tagged-p42(IP4) showed an enhanced NRD protein expression already at an earlier time point after RA stimulation.

Calcium-induced permeability transition in rat brain mitochondria is promoted by carbenoxolone through targeting connexin43.

Carbenoxolone (Cbx), a substance from medicinal licorice, is used for antiinflammatory treatments. We investigated the mechanism of action of Cbx on Ca(2+)-induced permeability transition pore (PTP) opening in synaptic and nonsynaptic rat brain mitochondria (RBM), as well as in rat liver mitochondria (RLM), in an attempt to identify the molecular target of Cbx in mitochondria. Exposure to threshold Ca(2+) load induced PTP opening, as seen by sudden Ca(2+) efflux from the mitochondrial matrix and membrane potential collapse. In synaptic RBM, Cbx (1 µM) facilitated the Ca(2+)-induced, cyclosporine A-sensitive PTP opening, while in nonsynaptic mitochondria the Cbx threshold concentration was higher. A well-known molecular target of Cbx is the connexin (Cx) family, gap junction proteins. Moreover, Cx43 was previously found in heart mitochondria and attributed to the preconditioning mechanism of protection. Thus, we hypothesized that Cx43 might be a target for Cbx in brain mitochondria. For the first time, we detected Cx43 by Western blot in RBM, but Cx43 was absent in RLM. Interestingly, two anti-Cx43 antibodies, directed against amino acids 252 to 270 of rat Cx43, abolished the Cbx-induced enhancement of PTP opening in total RBM and in synaptic mitochondria, but not in RLM. In total RBM and in synaptic mitochondria, PTP caused dephosphorylation of Cx43 at serine 368. The phosphorylation level of serine 368 was decreased at threshold calcium concentration and additionally in the combined presence of Cbx in synaptic mitochondria. In conclusion, active mitochondrial Cx43 appears to counteract the Ca(2+)-induced PTP opening and thus might inhibit the PTP-ensuing mitochondrial demise and cell death. Consequently, we suggest that activity of Cx43 in brain mitochondria represents a novel molecular target for protection.

The mitochondria permeability transition pore complex in the brain with interacting proteins - promising targets for protection in neurodegenerative diseases.

Mitochondria increasingly attract attention as control points within the mechanisms of neuronal death. Mitochondria play a central role in swinging the balance in favor of either survival or death of brain tissue. Cell death in vertebrates proceeds mostly via the mitochondrial pathway of apoptosis. Permeability transition pore (PTP) development in mitochondria is a decisive stage of apoptosis. Therefore, regulation of the permeability of both outer and inner mitochondrial membranes helps to induce neuroprotection. Through PTP control, mitochondria can to a large degree manage the intracellular calcium homeostasis, and thus control the potent death cascade initiated by excess calcium. Here we summarize the evidence for the role of mitochondria in brain cell death. We describe the involvement of the 18-kDa translocator protein (TSPO; previously called peripheral benzodiazepine receptor), and of two new mitochondrial proteins, that is, 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNP) and p42(IP4) (also designated centaurin alpha1; ADAP 1), in the control of the PTP. Furthermore, ligands of TSPO, as well as substrates of CNP, are possible modulators of PTP function. This scenario of control and regulation of PTP function might provide multiple important targets, which are suitable for developing protective strategies for neurons and non-neuronal brain cells in therapies of neurodegenerative diseases.

Ca2+-dependent permeability transition regulation in rat brain mitochondria by 2',3'-cyclic nucleotides and 2',3'-cyclic nucleotide 3'-phosphodiesterase.

Recent evidence indicates that 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNP), a marker enzyme of myelin and oligodendrocytes, is also present in neural and nonneural mitochondria. However, its role in mitochondria is still completely unclear. We found CNP in rat brain mitochondria and studied the effects of CNP substrates, 2',3'-cyclic nucleotides, on functional parameters of rat brain mitochondria. 2',3'-cAMP and 2',3'-cNADP stimulated Ca(2+) overload-induced Ca(2+) release from mitochondrial matrix. This Ca(2+) release under threshold Ca(2+) load correlated with membrane potential dissipation and mitochondrial swelling. The effects of 2',3'-cyclic nucleotides were suppressed by cyclosporin A, a potent inhibitor of permeability transition (PT). PT development is a key stage in initiation of apoptotic mitochondria-induced cell death. 2',3'-cAMP effects were observed on the functions of rat brain mitochondria only when PT was developed. This demonstrates involvement of 2',3'-cAMP in PT regulation in rat brain mitochondria. We also discovered that, under PT development, the specific enzymatic activity of CNP was reduced. Thus we hypothesize that suppression of CNP activity under threshold Ca(2+) load leads to elevation of 2',3'-cAMP levels that, in turn, promote PT development in rat brain mitochondria. Similar effects of 2',3'-cyclic nucleotides were observed in rat liver mitochondria. Involvement of CNP in PT regulation was confirmed in experiments using mitochondria from CNP-knockdown oligodendrocytes (OLN93 cells). CNP reduction in these mitochondria correlated with lowering the threshold for Ca(2+) overload-induced Ca(2+) release. Thus our results reveal a new function for CNP and 2',3'-cAMP in mitochondria, being a regulator/promotor of mitochondrial PT.

The brain-specific protein, p42(IP4) (ADAP 1) is localized in mitochondria and involved in regulation of mitochondrial Ca2+.

In brain, p42(IP4) (centaurin-alpha1; recently named ADAP 1, which signifies ADP ribosylation factor GTPase activating protein with dual PH domains 1, within the large family of Arf-GTPase activating proteins) is mainly expressed in neurons. p42(IP4) operates as a dual receptor recognising two second messengers, the soluble inositol(1,3,4,5)tetrakisphosphate and the lipid phosphatidylinositol(3,4,5)trisphosphate. We show here for the first time that p42(IP4) is localized in mitochondria, isolated from rat brain and from cells transfected with p42(IP4). In rat brain mitochondria we additionally found interaction of p42(IP4) with 2', 3'-cyclic nucleotide 3'-phosphodiesterase and alpha-tubulin by pull-down binding assay and by immunoprecipitation. In mitochondria from Chinese hamster ovary cells, p42(IP4) is predominantly associated with the intermembrane space and the inner membrane. This localization of p42(IP4) indicates that p42(IP4) might have a still unknown mitochondrial function. We studied whether p42(IP4) is involved in Ca(2+)-induced permeability transition pore opening, which is important in mitochondrial events leading to programmed cell death. We used mouse neuroblastoma cells as a model for the functional studies of p42(IP4) in mitochondria. In mitochondria isolated from p42(IP4)-transfected mouse neuroblastoma cells, over-expression of p42(IP4) significantly decreased Ca(2+) capacity and lag time for Ca(2+) retention. Thus, we suggest that p42(IP4) is involved in the regulation of Ca(2+) transport in mitochondria. We propose that p42(IP4) promotes Ca(2+)-induced permeability transition pore opening and thus destabilizes mitochondria.

Reduced neuronal co-localisation of nardilysin and the putative alpha-secretases ADAM10 and ADAM17 in Alzheimer's disease and Down syndrome brains.

The peptidase nardilysin is involved in degradation of neuropeptides and limited intracellular proteolysis. Recent reports point to an involvement of nardilysin in the pathophysiology of Alzheimer's disease. Nardilysin enhances the alpha-secretase activity of the disintegrin and metalloproteases (ADAMs) 10 and 17, thereby possibly contributing to reduced generation of amyloidogenic fragments from the amyloid precursor protein. A prerequisite for the alpha-secretase-stimulating effect of nardilysin on the activity of ADAMs in vivo is cellular co-expression of nardilysin with ADAM10 and/or ADAM17. We immunolocalised nardilysin, ADAM10, and ADAM17 in cortical regions of normal aged brain, in Alzheimer's disease, and in Down syndrome brains and counted the number of protease-expressing neurons. A considerable portion of neurons co-express nardilysin together with either ADAM10 or ADAM17. Compared to controls, in Alzheimer's disease and in Down syndrome brains there is a decreased cellular expression of all three antigens, and a reduction in the number of those neurons that co-express nardilysin with ADAM10 or with ADAM17. Our data are consistent with the notion that the proposed alpha-secretase-enhancing activity of nardilysin might play a role in human brain pathology.

Hetero-oligomerization of the P2Y11 receptor with the P2Y1 receptor controls the internalization and ligand selectivity of the P2Y11 receptor.

Nucleotides signal through purinergic receptors such as the P2 receptors, which are subdivided into the ionotropic P2X receptors and the metabotropic P2Y receptors. The diversity of functions within the purinergic receptor family is required for the tissue-specificity of nucleotide signalling. In the present study, hetero-oligomerization between two metabotropic P2Y receptor subtypes is established. These receptors, P2Y1 and P2Y11, were found to associate together when co-expressed in HEK293 cells. This association was detected by co-pull-down, immunoprecipitation and FRET (fluorescence resonance energy transfer) experiments. We found a striking functional consequence of the interaction between the P2Y11 receptor and the P2Y1 receptor where this interaction promotes agonist-induced internalization of the P2Y11 receptor. This is remarkable because the P2Y11 receptor by itself is not able to undergo endocytosis. Co-internalization of these receptors was also seen in 1321N1 astrocytoma cells co-expressing both P2Y11 and P2Y1 receptors, upon stimulation with ATP or the P2Y1 receptor-specific agonist 2-MeS-ADP. 1321N1 astrocytoma cells do not express endogenous P2Y receptors. Moreover, in HEK293 cells, the P2Y11 receptor was found to functionally associate with endogenous P2Y1 receptors. Treatment of HEK293 cells with siRNA (small interfering RNA) directed against the P2Y1 receptor diminished the agonist-induced endocytosis of the heterologously expressed GFP-P2Y11 receptor. Pharmacological characteristics of the P2Y11 receptor expressed in HEK293 cells were determined by recording Ca2+ responses after nucleotide stimulation. This analysis revealed a ligand specificity which was different from the agonist profile established in cells expressing the P2Y11 receptor as the only metabotropic nucleotide receptor. Thus the hetero-oligomerization of the P2Y1 and P2Y11 receptors allows novel functions of the P2Y11 receptor in response to extracellular nucleotides.

Interaction of the brain-specific protein p42IP4/centaurin-alpha1 with the peptidase nardilysin is regulated by the cognate ligands of p42IP4, PtdIns(3,4,5)P3 and Ins(1,3,4,5)P4, with stereospecificity.

The brain-specific protein p42IP4, also called centaurin-alpha1, specifically binds phosphatidylinositol 3,4,5-trisphosphate [PtdIns(3,4,5)P3] and inositol 1,3,4,5-tetrakisphosphate [Ins(1,3,4,5)P4]. Here, we investigate the interaction of p42IP4/centaurin-alpha1 with nardilysin (NRDc), a member of the M16 family of zinc metalloendopeptidases. Members of this peptidase family exhibit enzymatic activity and also act as receptors for other proteins. We found that p42IP4/centaurin-alpha1 binds specifically to NRDc from rat brain. We further detected that centaurin-alpha2, a protein that is highly homologous to p42IP4/centaurin-alpha1 and expressed ubiquitously, also binds to NRDc. In vivo interaction was demonstrated by co-immunoprecipitation of p42IP4/centaurin-alpha1 with NRDc from rat brain. The acidic domain of NRDc (NRDc-AD), which does not participate in catalysis, is sufficient for the protein interaction with p42IP4. Interestingly, preincubation of p42IP4 with its cognate ligands D-Ins(1,3,4,5)P4 and the lipid diC8PtdIns(3,4,5)P3 negatively modulates the interaction between the two proteins. D-Ins(1,3,4,5)P4 and diC8PtdIns(3,4,5)P3 suppress the interaction with virtually identical concentration dependencies. This inhibition is highly ligand specific. The enantiomer L-Ins(1,3,4,5)P4 is not effective. Similarly, the phosphoinositides diC8PtdIns(3,4)P2, diC8PtdIns(3,5)P2 and diC8PtdIns(4,5)P2 all have no influence on the interaction. Further experiments revealed that endogenous p42IP4 from rat brain binds to glutathione-S-transferase (GST)-NRDc-AD. The proteins dissociate from each other when incubated with D-Ins(1,3,4,5)P4, but not with inositol 1,4,5-trisphosphate [Ins(1,4,5)P3]. In summary, we demonstrate that p42IP4 binds to NRDc via the NRDc-AD, and that this interaction is controlled by the cognate cellular ligands of p42IP4/centaurin-alpha1. Thus, specific ligands of p42IP4 can modulate the recruitment of proteins, which are docked to p42IP4, to specific cellular compartments.

Protease-activated receptor-1 protects rat astrocytes from apoptotic cell death via JNK-mediated release of the chemokine GRO/CINC-1.

Thrombin at low doses is an endogenous mediator of protection in ischaemic and haemorrhagic models of stroke. However, the mechanism of thrombin-induced protection remains unclear. Recently accumulating evidence has shown that astrocytes play an important role in the brain after injury. We report that thrombin and thrombin receptor agonist peptide (TRag) up-regulated secretion of the chemokine growth-regulated oncogene/cytokine-induced neutrophil chemoattractant-1 (GRO/CINC-1) in primary rat astrocytes in a concentration-dependent manner. However, we found no increase of interleukin (IL)-6, IL-1beta and tumour necrosis factor-alpha secretion. Protease-activated receptor 1 (PAR-1)-induced GRO/CINC-1 release was mainly mediated by c-Jun N-terminal kinase (JNK) activation. Extracellular signal-regulated kinase 1/2 might be partially involved, but not p38 mitogen-activated protein kinase. Further studies demonstrated that PAR-1 activation, as well as application of recombinant GRO/CINC-1, protected astrocytes from C(2)-ceramide-induced cell death. Protection occurred with suppression of cytochrome c release from mitochondria. The inhibition of cytochrome c release was largely reduced by the antagonist of chemokine receptor CXCR2, SB-332235. Importantly, a specific JNK inhibitor significantly abolished the protective action of PAR-1. These results demonstrate for the first time that PAR-1 plays an important role in anti-apoptosis in the brain by regulating the release of chemokine GRO/CINC-1, which gives a feedback through its receptor CXCR2 to preserve astrocytes from toxic insults.