Analisi funzionale dei recettori per le neurotrofine p75NTR e Trka in neuroblastoma

The biological complexity of NGF action is achieved by binding two distinct Neurotrophin receptors, TrkA and p75NTR. While several reports have provided lines of evidence on the interaction between TrkA and p75NTR at the plasma membrane, much fewer data are available on the consequence of such an interaction in terms of intracellular signaling. In this study, we have focused on how p75NTR may affect TrkA downstream signaling with respect to neuronal differentiation. Here, we have shown that cooperation between p75NTR and TrkA results in an increased NGF-mediated TrkA autophosphorylation, leads to a sustained activation of ERK1/2 and accelerates neurite outgrowth. Interestingly, neurite outgrowth is concomitant with a selective enhancement of the AP-1 activity and the transcriptional activation of genes such as GAP-43 and p21(CIP/WAF), known to be involved in the differentiation process. Collectively, our results unveil a functional link between the specific expression profile of neurotrophin receptors in neuronal cells and the NGF-mediated regulation of the differentiation process possibly through a persistent ERKs activation and the selective control of the AP-1 activity. In our studies we discuss the functional role of the neurotrophin receptor p75NTR and TrkA in a ligand-dependent signal transduction. It is known that p75NTR is also involved in the mediation of cell death ligand dependent. Here we show for the first time that the membrane receptor p75NTR, upon binding to b- Amyloid (Ab) peptide, is able to transduce a cytotoxic signal through a mechanism very similar to the one adopted by Tumor Necrosis Factor Receptor 1 (TNFR1), when activated by TNFa. We define that in neuroblastoma cell line Ab cytotoxicity signals through a pathway depending on p75NTR death domain (DD), mostly through some specific conserved residues. We identified that TRADD is the first interactor recruiting to the membrane and activates JNK and NF-kB transcription factors. Since Ab is defined as the most important aetiologic element associated with the Alzheimer’s Disease (AD), characterization of the mechanism involved in the mediation of the neurodegeneration can suggest also new therapeutic approaches.

Studio di biomateriali usati come scaffold per Tissue Engineering e loro caratterizzazione con tecniche spettroscopiche vibrazionali e di analisi termica

This research investigated someone of the main problems connected to the application of Tissue Engineering in the prosthetic field, in particular about the characterization of the scaffolding materials and biomimetic strategies adopted in order to promote the implant integration. The spectroscopic and thermal analysis techniques were usefully applied to characterize the chemico-physical properties of the materials such as – crystallinity; – relative composition in case of composite materials; – Structure and conformation of polymeric and peptidic chains; – mechanism and degradation rate; – Intramolecular and intermolecular interactions (hydrogen bonds, aliphatic interactions). This kind of information are of great importance in the comprehension of the interactions that scaffold undergoes when it is in contact with biological tissues; this information are fundamental to predict biodegradation mechanisms and to understand how chemico-physical properties change during the degradation process. In order to fully characterize biomaterials, this findings must be integrated by information relative to mechanical aspects and in vitro and in vivo behavior thanks to collaborations with biomedical engineers and biologists. This study was focussed on three different systems that correspond to three different strategies adopted in Tissue Engineering: biomimetic replica of fibrous 3-D structure of extracellular matrix (PCL-PLLA), incorporation of an apatitic phase similar to bone inorganic phase to promote biomineralization (PCL-HA), surface modification with synthetic oligopeptides that elicit the interaction with osteoblasts. The characterization of the PCL-PLLA composite underlined that the degradation started along PLLA fibres, which are more hydrophylic, and they serve as a guide for tissue regeneration. Moreover it was found that some cellular lines are more active in the colonization of the scaffold. In the PCL-HA composite, the weight ratio between the polymeric and the inorganic phase plays an essential role both in the degradation process and in the biomineralization of the material. The study of self-assembling peptides allowed to clarify the influence of primary structure on intermolecular and intermolecular interactions, that lead to the formation of the secondary structure and it was possible to find a new class of oligopeptides useful to functionalize materials surface. Among the analytical techniques used in this study, Raman vibrational spectroscopy played a major role, being non-destructive and non-invasive, two properties that make it suitable to degradation studies and to morphological characterization. Also micro-IR spectroscopy was useful in the comprehension of peptide structure on oxidized titanium: up to date this study was one of the first to employ this relatively new technique in the biomedical field.