Persistent mitochondrial hyperpolarization (MHP) and enhanced calcium fluxing underlie aberrant T cell activation and death pathway selection in systemic lupus erythematosus. Treatment with rapamycin, which effectively controls disease activity, normalizes CD3/CD28-induced calcium fluxing but fails to influence MHP, suggesting that altered calcium fluxing is downstream or independent of mitochondrial dysfunction. In this article, we show that activity of the mammalian target of rapamycin (mTOR), which is a sensor of the mitochondrial transmembrane potential, is increased in lupus T cells. S ystemic lupus erythematosus (SLE)3 is an autoimmune disease of unknown etiology characterized by T and B cell dysfunction and production of antinuclear Abs (1). Dysregulation of cell death is thought to play a key role in driving antinuclear Ab production, since the source of immunogenic nuclear material is necrotic or apoptotic cells in SLE (2). There is enhanced spontaneous apoptosis of circulating T cells in SLE, which has been linked to chronic lymphopenia (3) and compartmentalized release of autoantigens (4). Paradoxically, there is decreased activation-induced T cell death in SLE (5-7), which may contribute to persistence of autoreactive cells.The mitochondria play crucial roles in activation and death pathway selection in T lymphocytes (2). Lupus T cells exhibit mitochondrial dysfunction, which is characterized by the elevation of the mitochondrial transmembrane potential (⌬ m ) or persistent mitochondrial hyperpolarization (MHP) and consequential ATP depletion, resulting in decrease of activation-induced apoptosis and predisposition of T cells for necrosis (6). ATP depletion in lupus T cells was recently confirmed by Krishnan et al. (8). We proposed that increased release of necrotic materials from T cells could drive disease pathogenesis by activating macrophages and dendritic cells and enhancing their capacity to produce NO and IFN-␣ in SLE (2). Indeed, dendritic cells exposed to necrotic, but not apoptotic, cells induce lupus like-disease in MRL mice and accelerate the disease of MRL/lpr mice (9).Enhanced T cell activation-induced calcium fluxing has been identified as a central defect in abnormal activation and cytokine production by lupus T cells (10). Induction of MHP and mitochondrial biogenesis by NO augments cytoplasmic calcium levels and regenerates the enhanced rapid calcium signaling profile of lupus T cells (11). Dysregulation of signaling through the TCR has also been shown to be a critical determinant of abnormal calcium fluxing in SLE (12, 13). The TCR/CD3 -chain (TCR) expression is diminished in SLE T cells, and it is functionally replaced by the FcR type I ␥-chain (FcRI␥), a protein normally found in other cell types (14). TCR signaling through FcRI␥ and its adaptor protein Syk is associated with elevated calcium fluxing but only in the absence of TCR (12). It has been shown that forced expression of The costs of publication of this article were defrayed in part by the payment of page charges. This ...
NOSTRIN: A protein modulating nitric oxide release and subcellular distribution of endothelial nitric oxide synthase
Activity and localization of endothelial nitric oxide synthase (eNOS) is regulated in a remarkably complex fashion, yet the complex molecular machinery mastering stimulus-induced eNOS translocation and trafficking is poorly understood. In a search by the yeast two-hybrid system using the eNOS oxygenase domain as bait, we have identified a previously uncharacterized eNOS-interacting protein, dubbed NOSTRIN (for eNOS traffic inducer). NOSTRIN contains a single polypeptide chain of 506-aa residues of 58 kDa with an N-terminal cdc15 domain and a Cterminal SH3 domain. NOSTRIN mRNA is abundant in highly vascularized tissues such as placenta, kidney, lung, and heart, and NOSTRIN protein is expressed in vascular endothelial cells. Coimmunoprecipitation experiments demonstrated the eNOS-NOSTRIN interaction in vitro and in vivo, and NOSTRIN's SH3 domain was essential and sufficient for eNOS binding. NOSTRIN colocalized extensively with eNOS at the plasma membrane of confluent human umbilical venous endothelial cells and in punctate cytosolic structures of CHO-eNOS cells. NOSTRIN overexpression induced a profound redistribution of eNOS from the plasma membrane to vesicle-like structures matching the NOSTRIN pattern and at the same time led to a significant inhibition of NO release. We conclude that NOSTRIN contributes to the intricate protein network controlling activity, trafficking, and targeting of eNOS. N itric oxide (NO) is a potent mediator in biological processes such as neurotransmission, inflammatory response, and vascular homeostasis (1). The prime source of NO in the cardiovascular system is endothelial NO synthase (eNOS), which is tightly regulated with respect to activity and localization. For example, coordinated phosphorylation contributes to activity control of eNOS because of activating and inhibiting phosphorylation at S1179 and T495, respectively (2-6). Myristoylation and dual palmitoylation at its extreme N terminus target eNOS to the cytoplasmic face of the Golgi complex and to the plasma membrane (7), where eNOS is thought to be fully capable of activation (8, 9). Misrouting of acylation-deficient eNOS impairs NO production (10, 11), indicating that correct subcellular targeting is critical for stimulus-dependent activation of the enzyme (8). Posttranslational modifications are efficiently complemented by multiple proteinprotein interactions that help regulate eNOS activity with respect to time and space. For instance, chaperone hsp90 bound to eNOS may mediate vascular endothelial growth factor-induced eNOS phosphorylation by promoting the interaction between eNOS and Akt (12, 13). At the plasma membrane, eNOS is complexed to and inhibited by the master components of caveolae, i.e., caveolin-1 in endothelial cells (9, 14) and caveolin-3 in cardiac myocytes (15). After stimulus-induced [Ca 2ϩ ] i increase, the Ca 2ϩ -calmodulin complex displaces eNOS from caveolin (16), stimulates eNOS to produce NO, and subsequently leads to the redistribution of eNOS from plasma membrane caveolae (17). The complexity...
Efficient transfer of proteins or nucleic acids across cellular membranes is a major problem in cell biology. Recently the existence of a fusogenic sequence was predicted in the junction area of the PreS2-and S-domain of the hepatitis-B virus surface antigens. We have identified cell permeability as a novel property of the PreS2-domain. Cell permeability of PreS2 is not restricted to hepatocytes. PreS2 translocates in an energy-independent manner into cells and is evenly distributed over the cytosol. Detailed analysis revealed that cell-permeability is mediated by an amphipatic ␣-helix between amino acids 41 and 52 of PreS2. Destruction of this translocation motif (PreS2-TLM) abolishes cell permeability. PreS2-TLM per se can act as a shuttle for peptides and functional proteins (such as EGFP). This permits the highly
Unlike most other endogenous messengers that are deposited in vesicles, processed on demand and/or secreted in a regulated fashion, NO (nitric oxide) is a highly active molecule that readily diffuses through cell membranes and thus cannot be stored inside the producing cell. Rather, its signalling capacity must be controlled at the levels of biosynthesis and local availability. The importance of temporal and spatial control of NO production is highlighted by the finding that differential localization of NO synthases in cardiomyocytes translates into distinct effects of NO in the heart. Thus NO synthases belong to the most tightly controlled enzymes, being regulated at transcriptional and translational levels, through co- and post-translational modifications, by substrate availability and not least via specific sorting to subcellular compartments, where they are in close proximity to their target proteins. Considerable efforts have been made to elucidate the molecular mechanisms that underlie the intracellular targeting and trafficking of NO synthases, to ultimately understand the cellular pathways controlling the formation and function of this powerful signalling molecule. In the present review, we discuss the mechanisms and triggers for subcellular routing and dynamic redistribution of NO synthases and the ensuing consequences for NO production and action.
Tumor necrosis factor α (TNF-α) is a proinflammatory cytokine. Its pleiotropic biological properties are signaled through two distinct cell surface receptors: the TNF receptor type I (TNFR-I) and the TNF receptor type II. Neither of the two receptors possesses tyrosine kinase activity. A large majority of TNF-α–dependent activities can be mediated by TNFR-I. Recently, c-Raf-1 kinase was identified as an intracellular target of a signal transduction cascade initiated by binding of TNF-α to TNFR-I. However, the mechanism engaged in TNF-α–dependent activation of c-Raf-1 kinase is still enigmatic.Here we report that the cytosolic adapter protein Grb2 is a novel binding partner of TNFR-I. Grb2 binds with its COOH-terminal SH3 domain to a PLAP motif within TNFR-I and with its NH2-terminal SH3 domain to SOS (son of sevenless). A PLAP deletion mutant of TNFR-I fails to bind Grb2. The TNFR-I/Grb2 interaction is essential for the TNF-α–dependent activation of c-Raf-1 kinase; activation of c-Raf-1 kinase by TNF-α can be blocked by coexpression of Grb2 mutants harboring inactivating point mutations in the NH2- or COOH-terminal SH3 domain, cell-permeable peptides that disrupt the Grb2/TNFR-I interaction or transdominant negative Ras. Functionality of the TNFR-I/Grb2/SOS/Ras interaction is a prerequisite but not sufficient for TNF-α–dependent activation of c-Raf-1 kinase. Inhibition of the TNFR-I/FAN (factor associated with neutral sphingomyelinase) interaction, which is essential for TNF-α–dependent activation of the neutral sphingomyelinase, either by cell-permeable peptides or by deletion of the FAN binding domain, prevents activation of c-Raf-1 kinase. In conclusion, binding of the Grb2 adapter protein via its COOH-terminal SH3 domain to the nontyrosine kinase receptor TNFR-I results in activation of a signaling cascade known so far to be initiated, in the case of the tyrosine kinase receptors, by binding of the SH2 domain of Grb2 to phosphotyrosine.
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