1,720,979 research outputs found
Therapeutic potential of pregnenolone and pregnenolone methyl ether on depressive and CDKL5 deficiency disorders: Focus on microtubule targeting
Full text linkPregnenolone methyl-ether (PME) is a synthetic derivative of the endogenous neuroactive steroid pregnenolone (PREG), which is an important modulator of several brain functions. In addition to being the precursor of steroids, PREG acts directly on various targets including microtubules (MTs), the functioning of which is fundamental for the development and homeostasis of nervous system. The coordination of MT dynamics is supported by a plethora of MT-associated proteins (MAPs) and by a specific MT code that is defined by the post-translational modifications of tubulin. Defects associated with MAPs or tubulin post-translational modifications are linked to different neurological pathologies including mood and neurodevelopmental disorders. In this review, we describe the beneficial effect of PME in major depressive disorders (MDDs) and in CDKL5 deficiency disorder (CDD), two pathologies that are joint by defective MT dynamics. Growing evidence indeed suggests that PME, as well as PREG, is able to positively affect the MT-binding of MAP2 and the plus-end tracking protein CLIP170 that are both found to be deregulated in the above mentioned pathologies. Furthermore, PME influences the state of MT acetylation, the deregulation of which is often associated with neurological abnormalities including MDDs. By contrast to PREG, PME is not metabolised into other downstream molecules with specific biological properties, an aspect that makes this compound more suitable for therapeutic strategies. Thus, through the analysis of MDDs and CDD, this work focuses attention on the possible use of PME for neuronal pathologies associated with MT defects
Rett syndrome: from the involved gene(s) to treatment
No full textRett syndrome (RTT) is a devastating genetic disorder that worldwide represents the most common genetic cause of severe intellectual disability in females. Most cases are caused by mutations in the X-linked MECP2 gene. The available molecular data suggest that MeCP2 is a key protein in the brain and that its level and functions cannot be altered without severe consequences in both genders. Importantly, in 2007, it was demonstrated that RTT in principle is a reversible condition and that MeCP2-related disorders can be treated even at late stages of disease progression. However, to develop clinical applications, the functional role(s) of MeCP2 and their relevance for RTT pathobiology must be clearly understood. This chapter presents current knowledge of MeCP2 functions and its etiological role in disease development, the most promising therapeutic strategies and those that may be relevant in the future, and the challenges associated with treating RTT
Microtubules: A Key to Understand and Correct Neuronal Defects in CDKL5 Deficiency Disorder?
No full textPBX1 nuclear export is regulated independently of PBX-MEINOX interaction by PKA phosphorylation of the PBC-B domain
Full text linkThe regulation of PBC protein function through subcellular distribution is a crucial evolutionarily conserved mechanism for appendage patterning. We investigated the processes controlling PBX1 nuclear export. Here we show that in the absence of MEINOX proteins nuclear export is not a default pathway for PBX1 subcellular localization. In different cell backgrounds, PBX1 can be imported or exported from the nucleus independently of its capacity to interact with MEINOX proteins. The cell context-specific balance between nuclear export and import of PBX1 is controlled by the PBC-B domain, which contains several conserved serine residues corresponding to phosphorylation sites for Ser/Thr kinases. PBX1 subcellular localization correlates with the phosphorylation state of these residues whose dephosphorylation induces nuclear export. Protein kinase A (PKA) specifically phosphorylates PBX1 at these serines, and stimulation of endogenous PKA activity in vivo blocks PBX1 nuclear export in distal limb mesenchymal cells. Our results reveal a novel mechanism for the control of PBX1 nuclear export in addition to the absence of MEINOX protein, which involves the inhibition of PKA-mediated phosphorylation at specific sites within the PBC-B domain
Characterization of PREP2, a paralog of PREP1, which defines a novel sub-family of the MEINOX TALE homeodomain transcription factors
Full text linkTALE (three amino acid loop extension) homeodomain proteins include the PBC and the MEINOX sub-families. MEINOX proteins form heterodimer complexes with PBC proteins. Heterodimerization is crucial to DNA binding and for nuclear localization. PBC-MEINOX heterodimers bind DNA also in combination with HOX proteins, thereby modulating their DNA-binding specificity. TALE proteins therefore play crucial roles in multiple developmental and differentiation pathways in vivo. We report the identification and characterization of a novel human gene homologous to PREP1, called PREP2. Sequence comparisons indicate that PREP1 and PREP2 define a novel sub-family of MEINOX proteins, distinct from the MEIS sub-family. PREP2 is expressed in a variety of human adult tissues and displays a more restricted expression pattern than PREP1. PREP2 is capable of heterodimerizing with PBC proteins. Heterodimerization with PBX1 appears to be essential for nuclear localization of both PREP2 and PBX1. A comparison between the functional properties of PREP1 and PREP2 reveals that PREP2-PBX display a faster DNA-dissociation rate than PREP1-PBX heterodimers, suggesting different roles in controlling gene expression. Like PREP1, PREP2-PBX heterodimers are capable of forming ternary complexes with HOXB1. The analysis of some PREP2 in vitro properties suggests a functional diversification among PREP and between PREP and MEIS MEINOX proteins
The subcellular localization of PBX1 and EXD proteins depends on nuclear import and export signals and is modulated by association with PREP1 and HTH
Full text linkNuclear localization of the Extradenticle (EXD) and PBX1 proteins is regionally restricted during Drosophila and mammalian development. We studied the subcellular localization of EXD, PBX, and their partners Homothorax (HTH) and PREP1, in different cell contexts. HTH and PREP1 are cytoplasmic and require association with EXD/PBX for nuclear localization. EXD and PBX1 are nuclear in murine fibroblasts but not in Drosophila Schneider cells, in which they are actively exported to the cytoplasm. Coexpression of EXD/PBX with HTH/PREP1 causes nuclear localization of their heterodimers in both cell contexts. We propose that heterodimerization with HTH/PREP induces nuclear translocation of EXD and PBX1 in specific cell contexts by blocking their nuclear export
Genetics and mechanisms of disease in Rett Syndrome
No full textRett syndrome is a severe X-linked neurodevelopmental disorder and the second most common cause of mental retardation in females. In addition to the classic form characterized by typical clinical manifestations, five variants have been described. Mutations in the MECP2 gene account for the majority of Rett cases, whereas genetic heterogeneity is associated with the variants. This review will focus on recently published work that reveals novel aspects of the molecular biology of Rett syndrome. © 2005 Elsevier Ltd. All rights reserved
Pregnenolone-methyl-ether enhances CLIP170 and microtubule functions improving spine maturation and hippocampal deficits related to CDKL5 deficiency
No full textMutations in the X-linked cyclin-dependent kinase-like 5 (CDKL5) cause CDKL5 deficiency disorder (CDD), a neurodevelopmental disease characterized by severe infantile seizures and intellectual disability. The absence of CDKL5 in mice causes defective spine maturation that can at least partially explain the cognitive impairment in CDKL5 patients and CDD mouse models. The molecular basis for such defect may depend on the capacity of CDKL5 to regulate microtubule (MT) dynamics through its association with the MT-plus end tracking protein CLIP170 (cytoplasmic linker protein 170). Indeed, we here demonstrate that the absence of CDKL5 causes CLIP170 to be mainly in a closed inactive conformation that impedes its binding to MTs. Previously, the synthetic pregnenolone analogue, pregnenolone-methyl-ether (PME), was found to have a positive effect on CDKL5-related cellular and neuronal defects in vitro. Here, we show that PME induces the open active conformation of CLIP170 and promotes the entry of MTs into dendritic spines in vitro. Furthermore, the administration of PME to symptomatic Cdkl5-knock-out mice improved hippocampal-dependent behavior and restored spine maturation and the localization of MT-related proteins in the synaptic compartment. The positive effect on cognitive deficits persisted for 1 week after treatment withdrawal. Altogether, our results suggest that CDKL5 regulates spine maturation and cognitive processes through its control of CLIP170 and MT dynamics, which may represent a novel target for the development of disease-modifying therapies
Patologia molecolare CDKL5 in una casistica di 170 individui non relati con disturbo pervasivo dello sviluppo e manifestazioni epilettiche ad insorgenza precoce
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