Fatima Macho Sanchez-Simon

Publications (2)8.16 Total impact

• Article: Morphine regulates dopaminergic neuron differentiation via miR-133b.

  Fatima Macho Sanchez-Simon, Xiao Xiao Zhang, Horace H Loh, Ping-Yee Law, Raquel E Rodriguez
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  ABSTRACT: Morphine is one of the analgesics used most to treat chronic pain, although its long-term administration produces tolerance and dependence through neuronal plasticity. The ability of morphine to regulate neuron differentiation in vivo has been reported. However, the detailed mechanisms have not yet been elucidated because of the inability to separate maternal influences from embryonic events. Using zebrafish embryos as the model, we demonstrate that morphine decreases miR-133b expression, hence increasing the expression of its target, Pitx3, a transcription factor that activates tyrosine hydroxylase and dopamine transporter. Using a specific morpholino to knock down the zebrafish μ-opioid receptor (zfMOR) in the embryos and selective mitogen-activated protein kinase inhibitors, we demonstrate that the morphine-induced miR-133b decrease in zebrafish embryos is mediated by zfMOR activation of extracellular signal-regulated kinase 1/2. A parallel morphine-induced down-regulation of miR-133b was observed in the immature but not in mature rat hippocampal neurons. Our results indicate for the first time that zebrafish embryos express a functional μ-opioid receptor and that zebrafish serves as an excellent model to investigate the roles of microRNA in neuronal development affected by long-term morphine exposure.
  Molecular pharmacology 11/2010; 78(5):935-42. · 4.53 Impact Factor
• Article: In vivo effects of morphine on neuronal fate and opioid receptor expression in zebrafish embryos.

  Fatima Macho Sanchez-Simon, Francisco J Arenzana, Raquel E Rodriguez
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  ABSTRACT: Morphine remains one of the most potent analgesic compounds used to control chronic pain despite its known adverse effects. It binds to the opioid receptors mu, delta and kappa, which are involved in aspects of neuronal fate such as cell proliferation, neuroprotection and neuronal differentiation. However, the effect of morphine on these processes is controversial and in vitro studies, as well as in vivo studies on adults and neonates in mammalian models, have not been able to clarify the diverse roles of morphine in the central nervous system. We have used zebrafish embryos to determine in vivo how morphine affects neuronal fate and opioid receptor gene expression and to elucidate if there is a link between these processes. Our results show that at 24 and 48 h post fertilization (hpf) morphine enhances cell proliferation, although it has opposing effects as an inducer of neuronal differentiation at these two stages, increasing the number of certain neuronal populations at 24 hpf and decreasing it at 48 hpf. The present study also demonstrates that in 24-hpf embryos morphine acts as a neuroprotector against glutamate damage in motor neurons and Pax-6-positive neurons. Furthermore, the gene expression of the opioid receptors is altered by embryonic exposition to morphine. In conclusion, our study sheds new light on the in vivo roles of morphine, and it indicates for the first time that its implication in cell proliferation and neuroprotection might be related to changes in the gene expression of opioid receptors.
  European Journal of Neuroscience 08/2010; 32(4):550-9. · 3.63 Impact Factor