Annalisa Vicario scite author profile

Alternatively spliced brain-derived neurotrophic factor (BDNF) transcripts are targeted to distinct cellular compartments in neurons but the mechanisms underlying this sorting are unknown. Although only some BDNF isoforms are targeted to dendrites, we have found that the coding region common to all BDNF transcripts contains a constitutively active dendritic targeting signal and that this signal is suppressed in transcripts containing exons 1 or 4, which are restricted to the cell soma and proximal dendrites. This dendritic targeting signal is mediated by translin, an RNA-binding protein implicated in RNA trafficking, and is disrupted by the G196A mutation associated with memory deficits and psychiatric disorders. Molecular modeling and mutational studies indicate that the G196A mutation blocks dendritic targeting of BDNF mRNA by disrupting its interaction with translin. These findings implicate abnormal dendritic trafficking of BDNF mRNA in the pathophysiology of neuropsychiatric disorders linked to the G196A mutation.neuropsychiatric disorders ͉ neurotrophins S everal lines of evidence indicate that targeting of BDNF mRNA to dendrites plays a key role in mediating synaptic plasticity (1-4). However, the molecular mechanisms regulating this process and the differential subcellular localization of alternatively spliced BDNF transcripts, remain to be clarified.Multiple BDNF transcripts are generated by alternative splicing of one 5Ј exon with a shared 3Ј exon containing the entire BDNF coding region and either a short or long 3Ј UTR sequence (5, 6). In recent studies, we have demonstrated that BDNF transcripts differ in their subcellular localization (7). Exon 1 and 4 transcripts are localized in the cell soma, while exon 2 and 6 transcripts show a somato-dendritic localization. Thus, splice variants appear to encode spatial localization signals used to preferentially regulate BDNF expression in different subcellular domains (2, 3). A recent study has suggested that the long 3Ј UTR contains signals necessary for dendritic targeting of BDNF transcripts (4). However, it is unlikely that this mechanism can fully account for the differential dendritic targeting displayed by BDNF transcripts because more than one-third of exon 4 transcripts, which are retained in the soma, contain the long 3Ј UTR. Conversely, more than one-half of exon 6 transcripts, an isoform that displays targeting to dendrites, contain the short 3Ј UTR. To help define the mechanisms underlying differential localization of BDNF transcripts, we have tested the hypothesis that additional signals might be encoded by other BDNF mRNA regions.

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Pro inflammatory stimuli enhance the immunosuppressive functions of adipose mesenchymal stem cells-derived exosomes

Domenis

Cifù

Quaglia

et al. 2018

Sci Rep

195

165

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The predominant mechanism by which adipose mesenchymal stem cells (AMSCs) participate to tissue repair is through a paracrine activity and their communication with the inflammatory microenvironment is essential part of this process. This hypothesis has been strengthened by the recent discovery that stem cells release not only soluble factors but also extracellular vesicles, which elicit similar biological activity to the stem cells themselves. We demonstrated that the treatment with inflammatory cytokines increases the immunosuppressive and anti-inflammatory potential of AMSCs-derived exosomes, which acquire the ability to shift macrophages from M1 to M2 phenotype by shuttling miRNA regulating macrophages polarization. This suggests that the immunomodulatory properties of AMSCs-derived exosomes may be not constitutive, but are instead induced by the inflammatory microenvironment.

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Genetic Dissection of Neurotrophin Signaling through the p75 Neurotrophin Receptor

et al. 2012

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Structural determinants underlying signaling specificity in the tumor necrosis factor receptor superfamily (TNFRSF) are poorly characterized, and it is unclear whether different signaling outputs can be genetically dissociated. The p75 neurotrophin receptor (p75(NTR)), also known as TNFRSF16, is a key regulator of trophic and injury responses in the nervous system. Here, we describe a genetic approach for dissecting p75(NTR) signaling and deciphering its underlying logic. Structural determinants important for regulation of cell death, NF-κB, and RhoA pathways were identified in the p75(NTR) death domain (DD). Proapoptotic and prosurvival pathways mapped onto nonoverlapping epitopes, demonstrating that different signaling outputs can be genetically separated in p75(NTR). Dissociation of c-Jun kinase (JNK) and caspase-3 activities indicated that JNK is necessary but not sufficient for p75(NTR)-mediated cell death. RIP2 recruitment and RhoGDI release were mechanistically linked, indicating that competition for DD binding underlies crosstalk between NF-κB and RhoA pathways in p75(NTR) signaling. These results provide insights into the logic of p75(NTR) signaling and pave the way for a genetic dissection of p75(NTR) function and physiology.

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BDNF and TrkB in neuronal differentiation of Fmr1-knockout mouse

Louhivuori

Vicario

Uutela

et al. 2011

Neurobiology of Disease

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Neuron-type-specific signaling by the p75NTR death receptor regulated by differential proteolytic cleavage

Vicario

Kisiswa

Tann

et al. 2015

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