Differenziamento macrofagico: gli effetti dei polimeri sintetici

Research for new biocompatible and easily implantable materials continuously proposes new molecules and new substances with biological, chemical and physical characteristics, that are more and more adapted to aesthetic and reconstructive surgery and to the development of biomedical devices such as cardiovascular prostheses. Two classes of polymeric biomaterials seem to meet better these requirements: “hydrogels” , which includes polyalkylimide (PAI) and polyvinylalcohol (PVA) and “elastomers”, which includes polyurethanes (PUs). The first ones in the last decade have had a great application for soft tissue augmentation, due to their similarity to this tissue for their high water content, elasticity and oxygen permeability (Dini et al., 2005). The second ones, on the contrary, are widely used in cardiovascular applications (catheters, vascular grafts, ventricular assist devices, total artificial hearts) due to their good mechanical properties and hemocompatibility (Zdrahala R.J. and Zdrahala I.J., 1999). In the biocompatibility evaluation of these synthetic polymers, that is important for its potential use in clinical applications, a fundamental aspect is the knowledge of the polymers cytotoxicity and the effect of their interaction with cells, in particular with the cell populations involved in the inflammatory responses, i.e. monocyte/macrophages. In consideration of what above said, the aim of this study is the comprehension of the in vitro effect of PAI, PVA and PU on three cell lines that represent three different stages of macrophagic differentiation: U937 pro-monocytes, THP-1 monocytes and RAW 264.7 macrophages. Cytotoxicity was evaluated by measuring the rate of viability with MTT, Neutral Red and morphological analysis at light microscope in time-course dependent experiments. The influence of these polymers on monocyte/macrophage activation in terms of cells adhesion, monocyte differentiation in macrophages, antigens distribution, aspecific phagocytosis, fluid-phase endocitosis, pro-inflammatory cytokine (TNF-α, IL-1β, IL-6) and nitric oxide (NO) release was evaluated. In conclusion, our studies have indicated that the three different polymeric biomaterials are highly biocompatible, since they scarcely affected viability of U937, THP-1 and RAW 264.7 cells. Moreover, we have found that even though hydrogels and polyurethane influences monocyte/macrophage differentiation (depending on the particular type of cell and polymer), they are immunocompatible since they not induced significantly high cytokine release. For these reasons their clinical applications are strongly encouraged.

Innovative therapeutic approaches for the atrophic Age-related Macular Degeneration (“dry” AMD)

Age related macular degeneration (AMD) is a major concern regarding blindness in the world. In western countries, where visual alterations due to minor pathologies as cataract and uncorrected refractive errors are easily resolved, AMD represent the main cause of blindness. Of the two existing forms of the disease, while the neovascular is more aggressive and progress quickly, geographic atrophy is the one still lacking an appropriate therapy. My PhD program was focused on investigating AMD features, trying to understand if some approaches I tested could be able to provide some suggestion about potential future therapies on “dry” AMD. In my research I developed three main projects. The most important part of the work regards the study of integrins and their fundamental role in cell adhesion in a context of interaction between retinal pigmented epithelium (RPE) and immune cells. I investigated how co-culture of these different cell lines can lead to simulate an inflammatory state inducing cell signaling, cytokine production and cell death. The use of integrin antagonists developed in our laboratory, showed how these effects can be reverted. A secondary approach regards the use of antioxidants and their role in epigenetic modifications in ARPE-19 cells to investigate how these compounds might exert their well-known protective role on AMD. Commonly used antioxidants as Lutein and Quercetin do not induce clear epigenetic modifications through histone H3 acetylation indicating only a limited involvement.

Investigating the mechanisms of Moraxella catarrhalis resistance to oxidative stress

Moraxella catarrhalis (Mcat) represents a human pathogen implicated in debilitating diseases, such as Chronic Obstructive Pulmonary Disease (COPD). One of the hallmarks of COPD is the excessive neutrophil oxidative stress mediated by reactive oxygen species (ROS). Mcat shows a higher innate level of resistance to exogenous oxidative stress compared to the co-infecting human airways pathogens such as non-typeable Haemophilus influenzae (NTHi) but the underlying mechanisms are currently not well defined. In this thesis, we demonstrated that, differently from NTHi, Mcat was able to directly interfere with ROS production and ROS-related responses such as neutrophil extracellular traps (NET) and autophagy in differentiated neutrophilic-like dHL-60 cells and primary cells. The underlying mechanisms were shown to be phagocytosis/opsonins-independent but contact-dependent, due to the engagement of the immunosuppressive receptors. Indeed, we identified that through OmpCD porin, Mcat was able to engage Siglec inhibitory receptors suppressing ROS generation by the host cells. Furthermore, Mcat provided a safer niche for the co-infecting NTHi bacterium which was otherwise susceptible to the host antimicrobial arsenal. Subsequently, to deeply characterize the Mcat global transcriptional response to oxidative stress, an RNA-Seq experiment was performed on exponentially growing bacteria exposed to sublethal amounts of H2O2 or CuSO4, stimuli that the pathogens experienced once they are phagocytosed. We unraveled a previously unidentified common transcriptional program following H2O2 and CuSO4 exposure, demonstrating a similar defense mechanism to the stress conditions encountered in neutrophils. We ascertained new crucial factors for this pathogen response and established a novel in vivo Mcat infection model, using the invertebrate Galleria mellonella. Actually, we observed that deletion mutants of genes implicated in oxidative stress resistance exhibited reduced virulence. In conclusion, this work represents an important step in the understanding of Mcat innate resistance mechanisms to oxidative stress and further elucidate the virulence mechanisms during infection.