Rapporti fra fattori ambientali e proteine di parete in Bifidobacterium

The normal gut microbiota has several important functions in host physiology and metabolism, and plays a key role in health and disease. Bifidobacteria, which are indigenous components of gastrointestinal microbiota, may play an important role in maintaining the well-being of the host although its precise function is very difficult to study. Its physiological and biochemical activities are controlled by many factors, particularly diet and environment. Adherence and colonization capacity are considered as contributing factors for immune modulation, pathogen exclusion, and enhanced contact with the mucosa. In this way, bifidobacteria would fortify the microbiota that forms an integral part of the mucosal barrier and colonization resistance against pathogens. Bifidobacteria are not only subjected to stressful conditions in industrial processes, but also in nature, where the ability to respond quickly to stress is essential for survival. Bifidobacteria, like other microorganisms, have evolved sensing systems for/and defences against stress that allow them to withstand harsh conditions and sudden environmental changes. Bacterial stress responses rely on the coordinated expression of genes that alter various cellular processes and structures (e.g. DNA metabolism, housekeeping genes, cell-wall proteins, membrane composition) and act in concert to improve bacterial stress tolerance. The integration of these stress responses is accomplished by regulatory networks that allow the cell to react rapidly to various and sometimes complex environmental changes. This work examined the effect of important stressful conditions, such as changing pH and osmolarity, on the biosynthesis of cell wall proteins in B. pseudolongum subsp. globosum. These environmental factors all influence heavily the expression of BIFOP (BIFidobacterial Outer Proteins) in the cell-wall and can have an impact in the interaction with host. Also evidence has been collected linking the low concentration of sugar in the culture medium with the presence or absence of extracromosomal DNA.

Sviluppo di mezzi e sistemi di sorveglianza e monitoraggio dei ditteri culicidi di importanza sanitaria

Nel corso degli ultimi anni le problematiche legate al ruolo vettore delle zanzare stanno emergendo sia per quanto riguarda l’uomo che gli animali allevati e selvatici. Diversi arbovirus come West Nile, Chikungunya, Usutu e Dengue, possono facilmente spostarsi a livello planetario ed essere introdotti anche nei nostri territori dove possono dare avvio a episodi epidemici. Le tecniche di monitoraggio e sorveglianza dei Culicidi possono essere convenientemente utilizzate per il rilevamento precoce dell’attività virale sul territorio e per la stima del rischio di epidemie al fine dell’adozione delle opportune azioni di Sanità Pubblica. Io scopo della ricerca del dottorato è inserito nel contesto dei temi di sviluppo del Piano regionale sorveglianza delle malattie trasmesse da vettori in Emilia Romagna. La ricerca condotta è inquadrata prevalentemente sotto l’aspetto entomologico applicativo di utilizzo di dispositivi (trappole) che possano catturare efficacemente possibili insetti vettori. In particolare questa ricerca è stata mirata allo studio comparativo in campo di diversi tipi di trappole per la cattura di adulti di zanzara, cercando di interpretare i dati per capire un potenziale valore di efficacia/efficienza nel rilevamento della circolazione virale e come supporto alla pianificazione della rete di sorveglianza dal punto di vista operativo mediante dispositivi adeguati alle finalità d’indagine. Si è cercato di trovare un dispositivo idoneo, approfondendone gli aspetti operativi/funzionali, ai fini di cattura del vettore principale del West Nile Virus, cioè la zanzara comune, da affiancare all’unica tipologia di trappola usata in precedenza. Le prove saranno svolte sia in campo che presso il laboratorio di Entomologia Medica Veterinaria del Centro Agricoltura Ambiente “G. Nicoli” di Crevalcore, in collaborazione con il Dipartimento di Scienze e Tecnologie Agroambientali della Facoltà di Agraria dell’Università di Bologna.

Cellular responses after exposure of lung cell cultures to secondary organic aerosol particles

The scope of this work was to examine in vitro responses of lung cells to secondary organic aerosol (SOA) particles, under realistic ambient air and physiological conditions occurring when particles are inhaled by mammals, using a novel particle deposition chamber. The cell cultures included cell types that are representative for the inner surface of airways and alveoli and are the target cells for inhaled particles. The results demonstrate that an exposure to SOA at ambient-air concentrations of about 10(4) particles/cm(3) for 2 h leads to only moderate cellular responses. There is evidence for (i) cell type specific effects and for (ii) different effects of SOA originating from anthropogenic and biogenic precursors, i.e. 1,3,5-trimethylbenzene (TMB) and alpha-pinene, respectively. There was no indication for cytotoxic effects but for subtle changes in cellular functions that are essential for lung homeostasis. Decreased phagocytic activity was found in human macrophages exposed to SOA from alpha-pinene. Alveolar epithelial wound repair was affected by TMB-SOA exposure, mainly because of altered cell spreading and migration at the edge of the wound. In addition, cellular responses were found to correlate with particle number concentration, as interleukin-8 production was increased in pig explants exposed to TMB-SOA with high particle numbers.

New exposure system to evaluate the toxicity of (scooter) exhaust emissions in lung cells in vitro

A constantly growing number of scooters produce an increasing amount of potentially harmful emissions. Due to their engine technology, two-stroke scooters emit huge amounts of adverse substances, which can induce adverse pulmonary and cardiovascular health effects. The aim of this study was to develop a system to expose a characterized triple cell coculture model of the human epithelial airway barrier, to freshly produced and characterized total scooter exhaust emissions. In exposure chambers, cell cultures were exposed for 1 and 2 h to 1:100 diluted exhaust emissions and in the reference chamber to filtered ambient air, both controlled at 5% CO(2), 85% relative humidity, and 37 degrees C. The postexposure time was 0-24 h. Cytotoxicity, used to validate the exposure system, was significantly increased in exposed cell cultures after 8 h postexposure time. (Pro-) inflammatory chemo- and cytokine concentrations in the medium of exposed cells were significantly higher at the 12 h postexposure time point. It was shown that the described exposure system (with 2 h exposure duration, 8 and 24 h postexposure time, dilution of 1:100, flow of 2 L/min as optimal exposure conditions) can be used to evaluate the toxic potential of total exhaust emissions.