L’inibizione della lattico deidrogenasi: una possibile strategia per migliorare il trattamento farmacologico del carcinoma epatocellulare

Il lavoro svolto nel corso del mio dottorato ha avuto per oggetto lo studio dell’ inibizione della glicolisi aerobia (il principale processo metabolico utilizzato dalle cellule neoplastiche per produrre energia) ottenuta mediante il blocco dell’enzima lattato deidrogenasi (LDH). La mia attività si è concentrata sulla possibilità di utilizzare questo approccio allo scopo di migliorare l’efficacia della terapia antitumorale, valutandone gli effetti su colture di carcinoma epatocellulare umano Inizialmente, per valutare gli effetti della inibizione della LDH, è stato usato l’acido ossamico ( OXA). Questo composto è l’unico inibitore noto specifico per LDH ; è una molecola non tossica in vivo, ma attiva a concentrazioni troppo elevate per consentirne un uso terapeutico. Un importante risultato ottenuto è stata la dimostrazione che l’ inibizione della LDH ottenuta con OXA non è solo in grado di innescare una risposta di morte nelle cellule trattate, ma, associata alla somministrazione di sorafenib, aumenta fortemente l’efficacia di questo farmaco, determinando un effetto di sinergismo. Questo forte effetto di potenziamento dell’azione del farmaco è stato spiegato con la dimostrazione che il sorafenib ha la capacità di inibire il consumo di ossigeno delle cellule trattate, rendendole più dipendenti dalla glicolisi. Grazie alla collaborazione con il Dipartimento di Scienze Farmaceutiche il nostro gruppo di ricerca è arrivato alla identificazione di un composto (galloflavina) che inibisce la LDH con una efficienza molto maggiore di OXA. I risultati preliminari ottenuti sulle cellule di epatocarcinoma suggeriscono che la galloflavina potrebbe essere un composto promettente nel campo degli inibitori metabolici tumorali e inducono a una sua valutazione più approfondita come potenziale farmaco antineoplastico.

The inhibition of aerobic glycolysis as a therapeutic approach to improve cancer chemotherapy

The aim of the research project discussed in this thesis was to study the inhibition of aerobic glycolysis, that is the metabolic pathway exploited by cancer cells for the ATP generation. This observation has led to the evaluation of glycolytic inhibitors as potential anticancer agents. Lactate dehydrogenase (LDH) is the only enzyme whose inhibition should allow a blocking of aerobic glycolysis of tumor cells without damaging the normal cells which, in conditions of normal functional activity and sufficient oxygen supply, do not need this enzyme. In preliminar experiments we demonstrated that oxamic acid and tartronic acid, two LDH competitive inhibitors, impaired aerobic glycolysis and replication of cells from human hepatocellular carcinoma. Therefore, we proposed that the depletion of ATP levels in neoplastic cells, could improved the chemotherapeutic index of associated anticancer drugs; in particular, it was studied the association of oxamic acid and multi-targeted kinase inhibitors. A synergistic effect in combination with sorafenib was observed, and we demonstrated that this was related to the capacity of sorafenib to hinder the oxidative phosphorylation, so that cells were more dependent to aerobic glycolysis. These results linked to LDH blockage encouraged us to search for LDH inhibitors more powerful than oxamic acid; thus, in collaboration with the Department of Pharmaceutical Sciences of Bologna University we identified a new molecule, galloflavin, able to inhibit both A and B isoforms of LDH enzyme. The effects of galloflavin were studied on different human cancer cell lines (hepatocellular carcinoma, breast cancer, Burkitt’s lymphoma). Although exhibiting different power on the tested cell lines, galloflavin was constantly found to inhibit lactate and ATP production and to induce cell death, mainly in the form of apoptosis. Finally, as LDH-A is able to bind single stranded DNA, thus stimulating cell transcription, galloflavin effects were also studied on this other LDH function.

Flow Field–Flow Fractionation for size analysis and characterization of nanoparticles for applications in Life Sciences

Nanotechnologies are rapidly expanding because of the opportunities that the new materials offer in many areas such as the manufacturing industry, food production, processing and preservation, and in the pharmaceutical and cosmetic industry. Size distribution of the nanoparticles determines their properties and is a fundamental parameter that needs to be monitored from the small-scale synthesis up to the bulk production and quality control of nanotech products on the market. A consequence of the increasing number of applications of nanomaterial is that the EU regulatory authorities are introducing the obligation for companies that make use of nanomaterials to acquire analytical platforms for the assessment of the size parameters of the nanomaterials. In this work, Asymmetrical Flow Field-Flow Fractionation (AF4) and Hollow Fiber F4 (HF5), hyphenated with Multiangle Light Scattering (MALS) are presented as tools for a deep functional characterization of nanoparticles. In particular, it is demonstrated the applicability of AF4-MALS for the characterization of liposomes in a wide series of mediums. Afterwards the technique is used to explore the functional features of a liposomal drug vector in terms of its biological and physical interaction with blood serum components: a comprehensive approach to understand the behavior of lipid vesicles in terms of drug release and fusion/interaction with other biological species is described, together with weaknesses and strength of the method. Afterwards the size characterization, size stability, and conjugation of azidothymidine drug molecules with a new generation of metastable drug vectors, the Metal Organic Frameworks, is discussed. Lastly, it is shown the applicability of HF5-ICP-MS for the rapid screening of samples of relevant nanorisk: rather than a deep and comprehensive characterization it this time shown a quick and smart methodology that within few steps provides qualitative information on the content of metallic nanoparticles in tattoo ink samples.