Mathieu Lesort

Insulin transiently increases tau phosphorylation: Involvement of glycogen synthase kinase-3β and Fyn tyrosine kinase

Abstract : The modulation of tau phosphorylation in response to insulin was examined in human neuroblastoma SH‐SY5Y cells. Insulin treatment resulted in a transient increase in tau phosphorylation followed by a decrease in tau phosphorylation that correlated directly with a sequential activation and deactivation of glycogen synthese kinase‐3β (GSK‐3β). The insulin‐induced increase in tau phosphorylation and concurrent activation of GSK‐3β was rapid (<2 min) and transient, and was associated with increased tyrosine phosphorylation of GSK‐3β. The increase in GSK‐3β tyrosine phosphorylation corresponded directly to an increase in the association of Fyn tyrosine kinase with GSK‐3β, and Fyn immunoprecipitated from cells treated with insulin for 1 min phosphorylated GSK‐3β to a significantly greater extent than Fyn immunoprecipitated from control cells. Subsequent to the increase in GSK‐3β activation and tau phosphorylation, treatment of cells with insulin for 60 min resulted in a dephosphorylation of tau and a decrease in GSK‐3β activity. Thus, insulin rapidly and transiently activated GSK‐3β and modulated tau phosphorylation, alterations that may contribute to neuronal plasticity.

Modulation of the in Situ Activity of Tissue Transglutaminase by Calcium and GTP

Tissue transglutaminase (tTG) is a calcium-dependent enzyme that catalyzes the posttranslational modification of proteins by transamidation of specific polypeptide-bound glutamine residues. Previous in vitro studies have demonstrated that the transamidating activity of tTG requires calcium and is inhibited by GTP. To investigate the endogenous regulation of tTG, a quantitative in situtransglutaminase (TG) activity assay was developed. Treatment of human neuroblastoma SH-SY5Y cells with retinoic acid (RA) resulted in a significant increase in tTG levels and in vitro TG activity. In contrast, basal in situ TG activity did not increase concurrently with RA-induced increased tTG levels. However, stimulation of cells with the calcium-mobilizing drug maitotoxin (MTX) resulted in increases in in situ TG activity that correlated (r 2 = 0.76) with increased tTG levels. To examine the effects of GTP on in situ TG activity, tiazofurin, a drug that selectively decreases GTP levels, was used. Depletion of GTP resulted in a significant increase in in situ TG activity; however, treatment of SH-SY5Y cells with a combination of MTX and tiazofurin resulted in significantly lessin situ TG activity compared with treatment with MTX alone. This raised the possibility of calcium-dependent proteolysis due to the effects of tiazofurin, because in vitro GTP protects tTG against proteolysis by trypsin. Studies with a selective membrane permeable calpain inhibitor indicated that tTG is likely to be an endogenous substrate of calpain, and that depletion of GTP increases tTG degradation after elevation of intracellular calcium levels. TG activity was also increased in response to activation of muscarinic cholinergic receptors, which increases intracellular calcium through inositol 1,4,5-trisphosphate generation. The results of these experiments demonstrate that selective changes in calcium and GTP regulate the activity and levels of tTGin situ.

Cystamine inhibits caspase activity. Implications for the treatment of polyglutamine disorders.

Huntingtons disease (HD) is an autosomal dominant neurodegenerative disorder caused by an abnormally expended polyglutamine domain. There is no effective treatment for HD; however, inhibition of caspase activity or prevention of mitochondria dysfunction delays disease progression in HD mouse models. Similarly administration of cystamine, which can inhibit transglutaminase, prolonged survival of HD mice, suggesting that inhibition of transglutaminase might provide a new treatment strategy. However, it has been suggested that cystamine may inhibit other thiol-dependent enzymes in addition to transglutaminase. In this study we show that cystamine inhibits recombinant active caspase-3 in a concentration-dependent manner. At low concentrations cystamine is an uncompetitive inhibitor of caspase-3 activity, becoming a non-competitive inhibitor at higher concentrations. The IC50 for cystamine-mediated inhibition of caspase-3 activity in vitro was 23.6 μm. In situ cystamine inhibited in a concentration-dependent manner the activation of caspase-3 by different pro-apoptotic agents. Additionally, cystamine inhibited caspase-3 activity to the same extent in cell lines stably overexpressing wild type tissue transglutaminase (tTG), a mutant inactive tTG, or an antisense for tTG, demonstrating that cystamine inhibits caspase activity independently of any effects it may have on the transamidating activity of tTG. Finally, treatment with cystamine resulted in a robust increase in the levels of glutathione. These findings demonstrate that cystamine may prolong neuronal survival and delay the onset of HD by inhibiting caspases and increasing the level of antioxidants such as glutathione.

Distinct Nuclear Localization and Activity of Tissue Transglutaminase

Tissue transglutaminase is a calcium-dependent transamidating enzyme that has been postulated to play a role in the pathology of expanded CAG repeat disorders with polyglutamine expansions expressed within the affected proteins. Because intranuclear inclusions have recently been shown to be a common feature of many of these codon reiteration diseases, the nuclear localization and activity of tissue transglutaminase was examined. Subcellular fractionation of human neuroblastoma SH-SY5Y cells demonstrated that 93% of tissue transglutaminase is localized to the cytosol. Of the 7% found in the nucleus, 6% copurified with the chromatin-associated proteins, and the remaining 1% was in the nuclear matrix fraction. In situ transglutaminase activity was measured in the cytosolic and nuclear compartments of control cells, as well as cells treated with the calcium-mobilizing agent maitotoxin to increase endogenous tissue transglutaminase activity. These studies revealed that tissue transglutaminase was activated in the nucleus, a finding that was further supported by cytochemical analysis. Immunofluorescence studies revealed that nuclear proteins modified by transglutaminase exhibited a discrete punctate, as well as a diffuse staining pattern. Furthermore, different proteins were modified by transglutaminase in the nucleus compared with the cytosol. The results of these experiments clearly demonstrate localization of tissue transglutaminase in the nucleus that can be activated. These findings may have important implications in the formation of the insoluble nuclear inclusions, which are characteristic of codon reiteration diseases such as Huntington’s disease and the spinocerebellar ataxias.

Tissue transglutaminase is essential for neurite outgrowth in human neuroblastoma SH-SY5Y cells.

Tissue transglutaminase is a normal constituent of the central and peripheral nervous systems and in rats transglutaminase activity in brain and spinal cord is highest during fetal stages when axonal outgrowth is occurring. Further, treatment of human neuroblastoma SH-SY5Y cells with retinoic acid results in the cells withdrawing from the cell cycle and extending neurites, in the same time frame that tissue transglutaminase expression significantly increases. Considering these and other previous findings, this study was carried out to determine whether tissue transglutaminase is involved in neuronal differentiation of SH-SY5Y cells. For these studies SH-SY5Y cells stably overexpressing wild-type tissue transglutaminase, an inactive tissue transglutaminase mutant (C277S) or an antisense tissue transglutaminase construct (which decreased endogenous tissue transglutaminase below detectable levels) were used. SH-SY5Y cells overexpressing wild-type tissue transglutaminase spontaneously differentiated into a neuronal phenotype when grown in low-serum media. In contrast, cells overexpressing inactive tissue transglutaminase or the antisense tissue transglutaminase continued to proliferate and exhibit a flat polygenic morphology even when maintained in low-serum conditions. In addition, increased tissue transglutaminase expression in response to retinoic acid was abolished in the antisense tissue transglutaminase cells, and antisense and mutant tissue transglutaminase expressing cells did not extend neurites in response to retinoic acid. Moreover, wild-type and inactive tissue transglutaminase exhibited differential intracellular localization. These data indicate that tissue transglutaminase is necessary and sufficient for neuronal differentiation of human neuroblastoma SH-SY5Y cells.

Insulin-like growth factor-1 and insulin mediate transient site-selective increases in tau phosphorylation in primary cortical neurons

The modulation of tau phosphorylation and localization in response to insulin-like growth factor-1 or insulin was examined in primary cultures of rat cortical neurons. Insulin and insulin-like growth factor-1 treatment resulted in a rapid and transient increase in tau phosphorylation at specific epitopes. These effects were completely inhibited by lithium, revealing that the insulin and insulin-like growth factor-1 induced changes in tau phosphorylation were mediated by glycogen synthase kinase-3beta. In addition, the increase in tau phosphorylation directly correlated with a transient dissociation of tau from the cytoskeleton, indicating that insulin and insulin-like growth factor-1 treatment resulted in a change in tau localization. Using immunocytochemistry, it was also demonstrated that treatment of neurons with insulin-like growth factor-1 for 3 min resulted in a redistribution of tau to the growth cone and the distal segment of the axons. Further, insulin-like growth factor-1 treatment resulted in an increased immunoreactivity with the phospho-dependent antibody AT8 in the same areas of the axons. Thus, the phosphorylation state and distribution of tau can be modulated by insulin and insulin-like growth factor-1 signaling pathways involving glycogen synthase kinase-3beta. We propose that by transiently increasing tau phosphorylation, insulin and insulin-like growth factor-1 may contribute to the reorganization of the cytoskeleton necessary for the development and growth of the neurites.

Early autophagic response in a novel knock-in model of Huntington disease

The aggregation of mutant polyglutamine (polyQ) proteins has sparked interest in the role of protein quality-control pathways in Huntingtons disease (HD) and related polyQ disorders. Employing a novel knock-in HD mouse model, we provide in vivo evidence of early, sustained alterations of autophagy in response to mutant huntingtin (mhtt). The HdhQ200 knock-in model, derived from the selective breeding of HdhQ150 knock-in mice, manifests an accelerated and more robust phenotype than the parent line. Heterozygous HdhQ200 mice accumulate htt aggregates as cytoplasmic aggregation foci (AF) as early as 9 weeks of age and striatal neuronal intranuclear inclusions (NIIs) by 20 weeks. By 40 weeks, striatal AF are perinuclear and immunoreactive for ubiquitin and the autophagosome marker LC3. Striatal NIIs accumulate earlier in HdhQ200 mice than in HdhQ150 mice. The earlier appearance of aggregate pathology in HdhQ200 mice is paralleled by earlier and more rapidly progressive motor deficits: progressive imbalance and decreased motor coordination by 50 weeks, gait deficits by 60 weeks and gross motor impairment by 80 weeks of age. At 80 weeks, heterozygous HdhQ200 mice exhibit striatal and cortical astrogliosis and a approximately 50% reduction in striatal dopamine receptor binding. Increased LC3-II protein expression, which is noted early and sustained throughout the disease course, is paralleled by increased expression of the autophagy-related protein, p62. Early and sustained expression of autophagy-related proteins in this genetically precise mouse model of HD suggests that the alteration of autophagic flux is an important and early component of the neuronal response to mhtt.

Glycogen synthase kinase-3β, β-catenin, and tau in postmortem bipolar brain

Summary. Therapeutic concentrations of the anti-bipolar drug lithium inhibit the activity of glycogen synthase kinase-3β, which raises the possibility that this enzyme and its substrates may be altered in the brain of subjects with bipolar disorder. Therefore, in prefrontal cortical samples from subjects with bipolar disorder and age-matched control subjects, we examined the levels of glycogen synthase kinase 3β and of two proteins modified by it, β-catenin and the microtubule associated protein tau. There were no significant differences between subject groups among these measurements, but there was a tendency for the tau isoform profile to be modified in bipolar tissue. Thus, while there are no differences between bipolars and controls in prefrontal cortical levels of glycogen synthase kinase-3β, β-catenin, or tau, tau isoform levels or phosphorylation states may be modified in bipolar disorder.

Enhanced Ca2 +-dependent glutamate release from astrocytes of the BACHD Huntington's disease mouse model

Huntingtons disease (HD) causes preferential loss of a subset of neurons in the brain although the huntingtin protein is expressed broadly in various neural cell types, including astrocytes. Glutamate-mediated excitotoxicity is thought to cause selective neuronal injury, and brain astrocytes have a central role in regulating extracellular glutamate. To determine whether full-length mutant huntingtin expression causes a cell-autonomous phenotype and perturbs astrocyte gliotransmitter release, we studied cultured cortical astrocytes from BACHD mice. Here, we report augmented glutamate release through Ca(2+)-dependent exocytosis from BACHD astrocytes. Although such release is usually dependent on cytosolic Ca(2+) levels, surprisingly, we found that BACHD astrocytes displayed Ca(2+) dynamics comparable to those in wild type astrocytes. These results point to a possible involvement of other factors in regulating Ca(2+)-dependent/vesicular release of glutamate from astrocytes. We found a biochemical footprint that would lead to increased availability of cytosolic glutamate in BACHD astrocytes: i) augmented de novo glutamate synthesis due to an increase in the level of the astrocyte specific mitochondrial enzyme pyruvate carboxylase; and ii) unaltered conversion of glutamate to glutamine, as there were no changes in the expression level of the astrocyte specific enzyme glutamine synthetase. This work identifies a new mechanism in astrocytes that could lead to increased levels of extracellular glutamate in HD and thus may contribute to excitotoxicity in this devastating disease.

Cystamine and cysteamine prevent 3‐NP‐induced mitochondrial depolarization of Huntington's disease knock‐in striatal cells

Cystamine significantly improved motor deficits and extended survival in mouse models of Huntingtons disease (HD); however, the precise mechanism(s) by which cystamine and the related compound cysteamine are beneficial remain to be elucidated. Using clonal striatal cell lines from wild‐type (STHdhQ7/HdhQ7) and mutant huntingtin knock‐in (STHdhQ111/HdhQ111) mice, we have tested the hypothesis that cystamine and cysteamine could be beneficial by preventing the depolarization of mitochondria in cell cultures. Treatment with 3‐nitroproprionic acid (3‐NP), a mitochondrial complex II inhibitor, induces mitochondrial depolarization and cell death of mutant HD striatal cells but not of wild‐type cells. The 3‐NP‐mediated decrease in the mitochondrial membrane potential was attenuated by 50 µm cystamine and completely inhibited by 250 µm cystamine. Similar results were obtained using cysteamine (50–500 µm). In addition, both cystamine and cysteamine significantly attenuated the 3‐NP‐induced cell death. Treatment of mutant HD striatal cells with 3‐NP resulted in a robust decrease in the cellular and mitochondrial levels of glutathione (GSH) compared with cells exposed to the vehicle alone. Pre‐treatment of the cells with cystamine and cysteamine completely prevented the 3‐NP‐mediated decrease in cellular and mitochondrial GSH levels. Incubation with l‐buthionine (S,R) sulfoximine (BSO) 250 µm in combination with cystamine (250 µm) or cysteamine (250 µm) prior to being treated with 3‐NP completely prevented the beneficial effects of cystamine and cysteamine on the 3‐NP‐mediated mitochondrial depolarization. These results demonstrate that cystamine and cysteamine prevent the 3‐NP‐induced mitochondrial depolarization of HD striatal cell cultures.