Post-transcriptional mechanisms controlling neurogenesis and direct neuronal reprogramming.

Neurogenesis is a tightly regulated process in time and space both in the developing embryo and in adult neurogenic niches. A drastic change in the transcriptome and proteome of radial glial cells or neural stem cells towards the neuronal state is achieved due to sophisticated mechanisms of epigenetic, transcriptional, and post-transcriptional regulation. Understanding these neurogenic mechanisms is of major importance, not only for shedding light on very complex and crucial developmental processes, but also for the identification of putative reprogramming factors, that harbor hierarchically central regulatory roles in the course of neurogenesis and bare thus the capacity to drive direct reprogramming towards the neuronal fate. The major transcriptional programs that orchestrate the neurogenic process have been the focus of research for many years and key neurogenic transcription factors, as well as repressor complexes, have been identified and employed in direct reprogramming protocols to convert non-neuronal cells, into functional neurons. The post-transcriptional regulation of gene expression during nervous system development has emerged as another important and intricate regulatory layer, strongly contributing to the complexity of the mechanisms controlling neurogenesis and neuronal function. In particular, recent advances are highlighting the importance of specific RNA binding proteins that control major steps of mRNA life cycle during neurogenesis, such as alternative splicing, polyadenylation, stability, and translation. Apart from the RNA binding proteins, microRNAs, a class of small non-coding RNAs that block the translation of their target mRNAs, have also been shown to play crucial roles in all the stages of the neurogenic process, from neural stem/progenitor cell proliferation, neuronal differentiation and migration, to functional maturation. Here, we provide an overview of the most prominent post-transcriptional mechanisms mediated by RNA binding proteins and microRNAs during the neurogenic process, giving particular emphasis on the interplay of specific RNA binding proteins with neurogenic microRNAs. Taking under consideration that the molecular mechanisms of neurogenesis exert high similarity to the ones driving direct neuronal reprogramming, we also discuss the current advances in in vitro and in vivo direct neuronal reprogramming approaches that have employed microRNAs or RNA binding proteins as reprogramming factors, highlighting the so far known mechanisms of their reprogramming action.

A miR-124-mediated post-transcriptional mechanism controlling the cell fate switch of astrocytes to induced neurons.

The microRNA (miRNA) miR-124 has been employed supplementary to neurogenic transcription factors (TFs) and other miRNAs to enhance direct neurogenic conversion. The aim of this study was to investigate whether miR-124 is sufficient to drive direct reprogramming of astrocytes to induced neurons (iNs) on its own and elucidate its independent mechanism of reprogramming action. Our data show that miR-124 is a potent driver of the reprogramming switch of astrocytes toward an immature neuronal fate by directly targeting the RNA-binding protein Zfp36L1 implicated in ARE-mediated mRNA decay and subsequently derepressing Zfp36L1 neurogenic interactome. To this end, miR-124 contribution in iNs' production largely recapitulates endogenous neurogenesis pathways, being further enhanced upon addition of the neurogenic compound ISX9, which greatly improves iNs' differentiation and functional maturation. Importantly, miR-124 is potent in guiding direct conversion of reactive astrocytes to immature iNs in vivo following cortical trauma, while ISX9 supplementation confers a survival advantage to newly produced iNs.

Regenerative Approaches in Huntington's Disease: From Mechanistic Insights to Therapeutic Protocols.

Huntington's Disease (HD) is a neurodegenerative disorder caused by a CAG expansion in the exon-1 of the IT15 gene encoding the protein Huntingtin. Expression of mutated Huntingtin in humans leads to dysfunction and ultimately degeneration of selected neuronal populations of the striatum and cerebral cortex. Current available HD therapy relies on drugs to treat chorea and control psychiatric symptoms, however, no therapy has been proven to slow down disease progression or prevent disease onset. Thus, although 24 years have passed since HD gene identification, HD remains a relentless progressive disease characterized by cognitive dysfunction and motor disability that leads to death of the majority of patients, on average 10-20 years after its onset. Up to now several molecular pathways have been implicated in the process of neurodegeneration involved in HD and have provided potential therapeutic targets. Based on these data, approaches currently under investigation for HD therapy aim on the one hand at getting insight into the mechanisms of disease progression in a human-based context and on the other hand at silencing mHTT expression by using antisense oligonucleotides. An innovative and still poorly investigated approach is to identify new factors that increase neurogenesis and/or induce reprogramming of endogenous neuroblasts and parenchymal astrocytes to generate new healthy neurons to replace lost ones and/or enforce neuroprotection of pre-existent striatal and cortical neurons. Here, we review studies that use human disease-in-a-dish models to recapitulate HD pathogenesis or are focused on promoting in vivo neurogenesis of endogenous striatal neuroblasts and direct neuronal reprogramming of parenchymal astrocytes, which combined with neuroprotective protocols bear the potential to re-establish brain homeostasis lost in HD.

A novel regulatory role of RGS4 in STAT5B activation, neurite outgrowth and neuronal differentiation.

The Regulator of G protein Signalling 4 (RGS4) is a multitask protein that interacts with and negatively modulates opioid receptor signalling. Previously, we showed that the δ-opioid receptor (δ-OR) forms a multiprotein signalling complex consisting of Gi/Go proteins and the Signal Transducer and Activator of Transcription 5B (STAT5B) that leads to neuronal differentiation and neurite outgrowth upon δ-ΟR activation. Here, we investigated whether RGS4 could participate in signalling pathways to regulate neurotropic events. We demonstrate that RGS4 interacts directly with STAT5B independently of δ-ΟR presence both in vitro and in living cells. This interaction involves the N-terminal portion of RGS4 and the DNA-binding SH3 domain of STAT5B. Expression of RGS4 in HEK293 cells expressing δ-OR and/or erythropoietin receptor results in inhibition of [D-Ser2, Leu5, Thr6]-enkephalin (DSLET)-and erythropoietin-dependent STAT5B phosphorylation and subsequent transcriptional activation. DSLET-dependent neurite outgrowth of neuroblastoma cells is also blocked by RGS4 expression, whereas primary cortical cultures of RGS4 knockout mice (RGS4-/-) exhibit enhanced neuronal sprouting after δ-OR activation. Additional studies in adult brain extracts from RGS4-/- mice revealed increased levels of p-STAT5B. Finally, neuronal progenitor cultures from RGS4-/- mice exhibit enhanced proliferation with concomitant increases in the mRNA levels of the anti-apoptotic STAT5B target genes bcl2 and bcl-xl. These observations suggest that RGS4 is implicated in opioid dependent neuronal differentiation and neurite outgrowth via a "non-canonical" signaling pathway regulating STAT5B-directed responses.

TGFß-induced early activation of the small GTPase RhoA is Smad2/3-independent and involves Src and the guanine nucleotide exchange factor Vav2.

TGFß has been shown to induce short- and long-term actin reorganization controlled by Rho-GTPase signaling. A number of direct Smad target genes, rapidly activated by TGFß, have been previously reported to control the long-term Rho activation and actin reorganization. However, the molecular mechanisms that regulate the prompt stimulation of Rho GTPases by TGFß remain unknown. In the present study we report that TGFß rapidly stimulated RhoA and RhoB activation in JEG3 choriocarcinoma cells that lack endogenous Smad3. Inhibition of Smad2 expression via siRNA-mediated silencing or by blocking its phosphorylation using the TßRI inhibitor SB431542 did not prevent the early RhoA/B activation by TGFß indicating that this effect is Smad2/3-independent. Pre-treatment of the cells with the general tyrosine kinase inhibitor Genistein blocked the TGFß-induced early RhoA activation. In line with this finding, TGFß-stimulation resulted in a quick activation of the non-receptor tyrosine kinase Src, followed by activation of the guanine nucleotide exchange factor (GEF) Vav2. Inhibition of Src kinase by the selective inhibitor of the Src family tyrosine kinases PP2 totally blocked the early TGFß-induced RhoA activation. Similarly, Vav2 silencing via siRNA reduced the TGFß-induced RhoA activation implying that the rapid Src/Vav2 stimulation was effective in regulating RhoA activation. Our present findings provide for the first time a clear evidence for the role of Src and Vav2-GEF in the early Smad2/3-independent Rho activation by TGFß.

Transcriptional regulation of the small GTPase RhoB gene by TGF{beta}-induced signaling pathways.

The purpose of the present study was to investigate the mechanism of transcriptional induction of the small GTPase RhoB gene by the transforming growth factor beta (TGFbeta) signaling pathway and the role of this regulation in TGFbeta-induced cell migration. To achieve our goals, we utilized a combination of siRNA-mediated gene silencing, adenovirus-mediated gene transfer receptor and MAPK inhibition, transactivation assays, and DNA-protein interaction assays in human HaCaT keratinocytes. We found that the RhoB gene is a direct transcriptional target of TGFbeta. We show that TGFbeta activates an early MEK/ERK pathway and that this activation is required for the recruitment of Smad3 to a novel, nonclassical, Smad binding element in the proximal RhoB promoter, in a p53-dependent manner. This element is overlapping with a CCAAT box that constitutively binds nuclear factor Y. Mutagenesis of this site abolished the Smad-mediated transactivation of the RhoB promoter. Finally, silencing of RhoB gene expression via siRNA or utilization of a dominant negative form of RhoB significantly inhibited TGFbeta-induced migration of HaCaT keratinocytes and DU145 prostate cancer cells. Our findings establish RhoB as a direct transcriptional target of TGFbeta in human keratinocytes and identify an important role of RhoB in TGFbeta-induced cell migration.-Vasilaki, E., Papadimitriou, E., Tajadura, V., Ridley, A. J., Stournaras, C., Kardassis, D. Transcriptional regulation of the small GTPase RhoB gene by TGFbeta-induced signaling pathways.

A novel mechanism of TGFbeta-induced actin reorganization mediated by Smad proteins and Rho GTPases.

In previous studies, we have demonstrated that RhoA/B-dependent signaling regulates TGFbeta-induced rapid actin reorganization in Swiss 3T3 fibroblasts. Here we report that TGFbeta regulates long-term actin remodeling by increasing the steady-state mRNA levels of the RhoB gene in mouse Swiss 3T3 fibroblasts and human hepatoma HepG2 cells. We show that this regulation is specific for the RhoB gene and is facilitated by enhanced activity of the RhoB promoter. Adenovirus-mediated gene transfer of Smad2 and Smad3 in Swiss 3T3 fibroblasts induced transcription of the endogenous RhoB gene but not the RhoA gene. Interestingly, in JEG-3 choriocarcinoma cells that lack endogenous Smad3, TGFbeta-induced transcriptional up-regulation of the RhoB gene was not observed, but it was restored by adenoviral Smad3 overexpression. In addition, Smad2 and Smad3 triggered activation of RhoA and RhoB GTPases and long-term actin reorganization in Swiss 3T3 fibroblasts. Finally, Smad3, and to a lesser extent Smad2, induced transcription of the alpha-smooth muscle actin (alpha-SMA) gene, and enhanced the incorporation of alpha-SMA into microfilaments in Swiss 3T3 fibroblasts. These data reveal a novel mechanism of cross-talk between the classical TGFbeta/Smad pathway and Rho GTPases, regulating the rapid and the long-term actin reorganization that may control the fibroblast-myofibroblast differentiation program.

Building an allergens ontology and maintaining it using machine learning techniques.

Ontologies are widely used for formalizing and organizing the knowledge of a particular domain of interest. This facilitates knowledge sharing and re-use by both people and systems. Ontologies are becoming increasingly important in the biomedical domain since they enable knowledge sharing in a formal, homogeneous and unambiguous way. Knowledge in a rapidly growing field such as biomedicine is usually evolving and therefore an ontology maintenance process is required to keep ontological knowledge up-to-date. This work presents our methodology for building a formally defined ontology, maintaining it exploiting machine learning techniques and domain specific corpora, and evaluating it using a well-defined experimental setting. The application of this methodology in the allergen domain is then discussed in detail presenting the ontology built, the specific techniques used and the evaluation settings.