Michel Pierre

Mechanisms of action in NIH-3T3 cells of genistein, an inhibitor of EGF receptor tyrosine kinase activity.

Genistein has been shown to inhibit specifically in vitro the epidermal growth factor (EGF)-receptor tyrosine protein kinase activity (Akiyama et al., J Biol Chem 262: 5592-5597, 1987). When the effects of genistein on NIH-3T3 cells were studied, a cytostatic effect was observed at low concentration (less than 40 microM) and a cytotoxic effect at higher concentration (greater than 40 microM). Genistein was able to block the mitogenic effect mediated by EGF on NIH-3T3 cells (IC50 = 12 microM) or by insulin (IC50 = 19 microM). Genistein was also able to block the mitogenic effect mediated by thrombin (IC50 = 20 microM) although the thrombin receptor does not involve a protein tyrosine kinase activity. Genistein at cytostatic concentration (less than 40 microM) did not prevent the induction of c-myc mRNA synthesis caused by the activation of EGF receptor by EGF. Therefore the cytostatic effect of genistein on NIH-3T3 cells did not appear to be mediated by EGF receptor tyrosine kinase inhibition. This hypothesis was also supported by the absence of effect of genistein on the EGF-stimulated phosphorylation of several proteins and particularly of a cytosolic 80 kD protein. The stimulation of S6 kinase activity of cells treated by EGF was prevented by genistein. The stimulation by EGF of in situ S6 phosphorylation was also prevented by genistein. In addition, S6 kinase extracted from cells treated by EGF was inhibited by genistein. These effects occur at similar doses and maximal inhibition of S6 kinase was obtained at about 15 microM.

MAP kinase activation by fluoxetine and its relation to gene expression in cultured rat astrocytes

Chronic treatments with antidepressants active on major depressive disorders influence pathways involved in cell survival and plasticity. As astrocytes seem to play a key role in the protection of brain cells, we investigated in these cells the rapid effects of the antidepressant fluoxetine (Prozac®) on signaling cascades and gene induction, which probably play a role in neuroprotection. We show here that fluoxetine alone activates the extracellular signal-regulated-protein kinase (Erk) and p38 mitogen-associated protein (MAP) kinase cascades. RT-PCR revealed that genes, modulated in brain by long-term fluoxetine treatment, are rapidly induced (detectable after 2–4 h) by fluoxetine in cultured astrocytes: brain-derived nerve factor (BDNF) and its receptors, glialderived nerve factor (GDNF) and deiodinase 3 (D3). Induction of D3 by fluoxetine is inhibited by U0126 and SB203580, suggesting that Erk and p38 MAP kinases are involved. Glial-derived nerve factor (GDNF) induction by fluoxetine is prevented by U0126, suggesting that Erk is implicated. Brain-derived nerve factor (BDNF) induction seems mediated by other signaling pathways. In conclusion, we show that fluoxetine alone rapidly activates mitogen activated protein (MAP) kinase cascades in rat astrocytes and that genes involved in neuroprotection are induced in a few hours in a MAP kinase-dependent or -independent manner.

MAP Kinase Cascades Are Activated in Astrocytes and Preadipocytes by 15-Deoxy-Δ12–14-prostaglandin J2 and the Thiazolidinedione Ciglitazone through Peroxisome Proliferator Activator Receptor γ-independent Mechanisms Involving Reactive Oxygenated Species

15-Deoxy-Δ12–14-prostaglandin J2 (dPGJ2) and thiazolidinediones are known as ligands for the peroxisome proliferator activator receptor γ (PPARγ) a member of the nuclear receptor superfamily. Herein, we show that dPGJ2 activates, in cultured primary astrocytes, Erk, Jnk, p38 MAP kinase, and ASK1, a MAP kinase kinase kinase, which can be involved in the activation of Jnk and p38 MAP kinase. The activation kinetic is similar for the three MAP kinase. The activation of the MAP kinases is detectable around 0.5 h. The activation increases with dPGJ2 in a dose dependent manner (0–15 μm). A scavenger of reactive oxygenated species (ROS), N-acetylcysteine (NAC) at 20 mm, completely suppresses the activation of MAP kinases and ASK1, suggesting a role for oxidative stress in the activation mechanism. Other prostaglandin cyclopentenones than dPGJ2, A2, and to a lesser degree, A1 also stimulate the MAP kinases, although they do not bind to PPARγ. Ciglitazone (20 μm), a thiazolidinedione that mimics several effects of dPGJ2 in different cell types, also activates the three MAP kinase families and ASK1 in cultured astrocytes. However the activation is more rapid (it is detectable at 0.25 h) and more sustained (it is still strong after 4 h). NAC prevents the activation of the three MAP kinase families by ciglitazone. Another thiazolidinedione that binds to PPARγ, rosiglitazone, does not activate MAP kinases, indicating that the effect of ciglitazone on MAP kinases is independent of PPAR γ. Ciglitazone and less strongly dPGJ2 activate Erk in undifferentiated cells of the adipocyte cell line 1B8. Ciglitazone also activates Jnk and p38 MAP kinase in these preadipocytes. Our findings suggest that a part of the biological effects of dPGJ2 and ciglitazone involve the activation of the three MAP kinase families probably through PPARγ-independent mechanisms involving ROS.

Induction of 5‐Deiodinase Activity in Astroglial Cells by 12‐O‐Tetradecanoylphorbol 13‐Acetate and Fibroblast Growth Factors

Abstract: In the brain, 5′‐deiodinase (5′‐D) is responsible for the metabolic activation of thyroxine (T4) into 3,5,3′‐triiodothyronine (T3) and 5‐deiodinase (5‐D) deiodinates T4 and T3 into inactive metabolites. This study examines the effects of factors known to induce astroglial 5′‐D activity on the 5‐D activity in cultured rat astroglial cells. The potencies of these factors were compared after 8 h of incubation, when stimulations by these factors near their maximal effects. 12‐O‐Tetradecanoylphorbol 13‐acetate (TPA) at 10−7M was a potent inducer of 5‐D activity, producing a 30‐ to 80‐fold increase after 8 h. The maximal effect of TPA was observed after about 14 h. The TPA stimulation of 5‐D activity was not dependent on glucocorticoids, unlike 5′‐D activity. In comparison with TPA, 8‐bromo‐cyclic AMP (10−3M) was a poor inducer of 5‐D activity whereas it is an excellent inducer of 5′‐D activity. It produced a 2‐ to 20‐fold increase in 5‐D activity after 8 h. Natural acidic fibroblast growth factor (20 ng/ml) produced a degree of stimulation similar to that of TPA after 8 h. The maximal effect of acidic fibroblast growth factor was observed after about 16 h (until a 120‐fold increase). Recombinant acidic fibroblast growth factor also induced 5‐D activity. Basic fibroblast growth factor was less potent than acidic fibroblast growth factor for increasing 5‐D activity (maximal increase by 40‐ to 50‐fold after 8 h). Platelet‐derived growth factor (20 ng/ml) and epidermal growth factor (100 ng/ml) were poor inducers of 5‐D activity (8‐ to 12‐fold increase at 8 h); insulin (10−6M) was without effect. The 5‐D activity induced by TPA and acidic fibroblast growth factor manifested the characteristics of type III 5‐D (Km for T3 0.5–0.8 nM, thiol‐dependent, 6‐n‐propyl‐2‐thiouracil‐insensitive). The results demonstrate that, like 5′‐D activity, 5‐D activity is induced by multiple pathways. The relative potencies of TPA, fibroblast growth factors, and cyclic AMP on 5‐D and 5′‐D activities were different, as were the time courses of their actions. These data indicate that 5‐ and 5′‐D are distinct enzymes and support the view that T3 availability may be controlled not only by regulating T3 production, but also by regulating T3 and T4 degradation.

Regulation of Type 3 Iodothyronine Deiodinase Expression in Cultured Rat Astrocytes: Role of the Erk Cascade

The type 3 iodothyronine deiodinase (D3) metabolizes thyroid hormones to inactive metabolites in many tissues, including the brain. In the present studies, we have examined the mechanisms by which T3 (T3), retinoic acid, 12-O-tetradecanoyl phorbol 13-acetate (TPA), and basic fibroblast growth factor (bFGF) induce D3 expression in primary cultures of neonatal rat astrocytes. In untreated cells, D3 messenger RNA (mRNA) was essentially undetectable by Northern analysis and RT-PCR. However, all four agents induced expression of a 2.4-kb D3 transcript as well as D3 activity. Induction of D3 by TPA and bFGF was more rapid than that by T3 and retinoic acid, and T3 potentiated the stimulatory effects of TPA and bFGF. D3 induction by TPA was blocked by GF 109203X, an inhibitor of protein kinase C. In addition, the effects of TPA and bFGF were partially prevented by PD 98059, a specific inhibitor of MEK and the Erk signaling cascade. These studies demonstrate that multiple growth factors and hormones regulate D3 ac...

Oxidative Stress Regulates Type 3 Deiodinase and Type 2 Deiodinase in Cultured Rat Astrocytes

Type 2 deiodinase (D2) and type 3 deiodinase (D3) locally achieve the determination of the concentration of T3, which binds to the thyroid hormone receptor with high affinity. D2 converts T4 into T3, and D3 degrades T4 and T3. Neurons take up T3 released by astrocytes, the main cerebral site for the D2 expression. Because oxidative stress is believed to be involved in several neurological disorders, we explored the effects of oxidative stress on D3 and D2 in primary culture of rat astrocytes. H2O2 (250 microm) increased D3 activity with maximal effects around 8 h. Stimulation of D3 activity by H2O2 was synergistic with T4, phorbol ester, and also cAMP. H2O2 (250 microm) did not affect basal D2 activity but inhibited the stimulation of D2 activity by cAMP and factors implicating cAMP-independent pathways in astrocytes, TSH, and phorbol ester. N-Acetyl cysteine and selenium repletion, which respectively increase intracellular glutathione and glutathione peroxidase, inhibited D2 and D3 regulation by H2O2, whereas L-buthionine sulfoximine, which decreases intracellular glutathione, mimicked H2O2 effects. Oxidative stress up-regulated D3 and inhibited cAMP-stimulated D2 by transcriptional mechanisms. A decrease in cAMP by oxidative stress could contribute to the inhibition of cAMP-stimulated D2. Using specific inhibitors of signaling pathways, we show that the ERK pathway was required in D2 and D3 regulation by oxidative stress and that the p38 MAPK pathway was implicated in H2O2-induced D3. We suggest that the expected decrease in T3 might modulate the cellular injury of oxidative stress in some pathological brain conditions.

Multisite phosphorylation of τ proteins from rat brain

Abstract τ proteins from adult and young rat brains were phosphorylated in vitro by protein kinases present in microtubule preparations. Several phosphates were incorporated in each molecular species of this group of proteins. Cyclic AMP dependent protein kinases and casein kinase (type I) phosphorylated τ proteins on different sites. These observations indicate that τ proteins are an example of multisite phosphorylation.

Induction of Type 3 Iodothyronine Deiodinase by Nerve Injury in the Rat Peripheral Nervous System

Thyroid hormones are essential for the development and repair of the peripheral nervous system. The type 2 deiodinase, which is responsible for the activation of T4 into T3, is induced in injured sciatic nerve. To obtain information on the type 3 deiodinase (D3) responsible for the degradation of thyroid hormones, we looked for its expression (mRNA and activity) in the sciatic nerve after injury. D3 was undetectable in the intact sciatic nerve of adult rats, but was rapidly and highly increased in the distal and proximal segments after nerve lesion. After cryolesion, D3 up-regulation disappeared after 3 d in the proximal segment, whereas it was sustained for 10 d in the distal segment, then declined to reach basal levels after 28 d, when functional recovery was completed. After a transsection preventing the nerve regeneration, up-regulation of D3 persisted up to 28 d at high levels in the distal segment. D3 was expressed in peripheral connective sheaths and in the internal endoneural compartment. D3 mRNA ...

The role of MAP kinases in rapid gene induction after lesioning of the rat sciatic nerve

Lesion of the sciatic nerve caused a rapid activation of p38MAP kinase in the injured nerve adjacent to the site of transection. This activation was detectable 3 min after lesioning, increased during the next 15 min and remained high for several hours. Erk1/2 activation was also observed as early as 15 min after lesioning. Activation of these MAP kinases was seen in both the external sheaths and the endoneurium. The separation of the external sheaths from the endoneurium accelerated the p38MAP kinase activation. To evaluate whether the injury‐activated MAP kinase cascades are implicated in the rapid gene induction observed after nerve lesion, experiments were performed with an ex vivo model. Segments of sciatic nerves were incubated in oxygenated Krebs–Ringer buffer. MAP kinases were activated at 15 min and remained active after 6 h. Induction of mRNA was also observed for nerve growth factor (NGF), interleukin 6 (IL‐6), leukaemia inhibitory factor (LIF) and deiodinases of type 2 (D2) and type 3 (D3). Thus, the ex vivo model mimics events occurring in the animal after nerve section. Finally, nerve segments were incubated in the presence of specific inhibitors of Erk1/2 activation (U0126) and of p38MAP kinase activity (SB203580). U0126 inhibited D3, LIF and to a lesser extent NGF mRNA induction, but did not affect significantly the induction of D2 and IL‐6 mRNAs. SB203580 inhibited the expression of the genes for D3 and LIF. We conclude that MAP kinase cascades, activated by nerve transection, are involved in the rapid gene induction in the nerve.

Insulin and insulin-like growth factor 1 receptors during postnatal development of rat brain

The binding of insulin and insulin-like growth factor 1 (IGF1) to high-affinity sites in the brain of rats aged 2-37 days was studied. Specific binding of insulin and IGF1 was assessed using tracer concentrations of 125I-insulin or 125I-IGF1. Sites for insulin and IGF1 were distinguished in these conditions as shown by competition experiments. The Kd were 3.6 nM (insulin) and 2.0 nM (IGF1). These values did not change significantly over the age range studied. The numbers of high-affinity binding sites for insulin and IGF1 were similar in adult animals. IGF1 binding was higher than the insulin binding in 2-day-old animals. The binding capacity for both insulin and IGF1 decreased from birth to age 15 and days remained stable thereafter. Tyrosine kinase activity, which is associated with these receptors, was measured using the artificial substrate poly (Glu, Tyr). It decreased over the first 15 days of life and remained stable thereafter. Autophosphorylation of the receptors confirmed this result. This decrease appears to be due to changes in the numbers of the two types of receptors, and is probably a reflection mainly of the variation in the number of IGF1 receptors. Similar results for insulin and IGF1 binding as well as tyrosine kinase activity were obtained with hypothyroid rats.