Synthesis and surface modification of silver and gold nanoparticles. Nanomedicine applications against Glioblastoma Multiforme.

In the last decades noble metal nanoparticles (NPs) arose as one of the most powerful tools for applications in nanomedicine field and cancer treatment. Glioblastoma multiforme (GBM), in particular, is one of the most aggressive malignant brain tumors that nowadays still presents a dramatic scenario concerning median survival. Gold nanorods (GNRs) and silver nanoparticles (AgNPs) could find applications such as diagnostic imaging, hyperthermia and glioblastoma therapy. During these three years, both GNRs and AgNPs were synthesized with the “salt reduction” method and, through a novel double phase transfer process, using specifically designed thiol-based ligands, lipophilic GNRs and AgNPs were obtained and separately entrapped into biocompatible and biodegradable PEG-based polymeric nanoparticles (PNPs) suitable for drug delivery within the body. Moreover, a synergistic effect of AgNPs with the Alisertib drug, were investigated thanks to the simultaneous entrapment of these two moieties into PNPs. In addition, Chlorotoxin (Cltx), a peptide that specifically recognize brain cancer cells, was conjugated onto the external surface of PNPs. The so-obtained novel nanosystems were evaluated for in vitro and in vivo applications against glioblastoma multiforme. In particular, for GNRs-PNPs, their safety, their suitability as optoacoustic contrast agents, their selective laser-induced cells death and finally, a high tumor retention were all demonstrated. Concerning AgNPs-PNPs, promising tumor toxicity and a strong synergistic effect with Alisertib was observed (IC50 10 nM), as well as good in vivo biodistribution, high tumor uptake and significative tumor reduction in tumor bearing mice. Finally, the two nanostructures were linked together, through an organic framework, exploiting the click chemistry azido-alkyne Huisgen cycloaddition, between two ligands previously attached to the NPs surface; this multifunctional complex nanosystem was successfully entrapped into PNPs with nanoparticles’ properties maintenance, obtaining in this way a powerful and promising tool for cancer fight and defeat.

The impact of phosphoinositide metabolic enzymes in glioblastoma: a tale of phosphoinositide-specific phospholipase C PLCβ1 and 5-phosphatase SKIP

Background: Glioblastoma multiforme (GBM) is one of the deadliest and most aggressive form of primary brain tumor. Unfortunately, current GBM treatment therapies are not effective in treating GBM patients. They usually experience very poor prognosis with a median survival of approximately 12 months. Only 3-5% survive up to 3 years or more. A large-scale gene profile study revealed that several genes involved in essential cellular processes are altered in GBM, thus, explaining why existing therapies are not effective. The survival of GBM patients depends on understanding the molecular and key signaling events associated with these altered physiological processes in GBM. Phosphoinositides (PI) form just a tiny fraction of the total lipid content in humans, however they are implicated in almost all essential biological processes, such as acting as second messengers in spatio-temporal regulation of cell signaling, cytoskeletal reorganization, cell adhesion, migration, apoptosis, vesicular trafficking, differentiation, cell cycle and post-translational modifications. Interestingly, these essential processes are altered in GBM. More importantly, incoming reports have associated PI metabolism, which is mediated by several PI phosphatases such as SKIP, lipases such as PLCβ1, and other kinases, to regulate GBM associated cellular processes. Even as PLCβ1 and SKIP are involved in regulating aberrant cellular processes in several other cancers, very few studies, of which majority are in-silico-based, have focused on the impact of PLCβ1 and SKIP in GBM. Hence, it is important to employ clinical, in vitro, and in vivo GBM models to define the actual impact of PLCβ1 and SKIP in GBM. AIM: Since studies of PLCβ1 and SKIP in GBM are limited, this study aimed at determining the pathological impact of PI metabolic enzymes, PLCB1 and SKIP, in GBM patient samples, GBM cell line models, and xenograft models for SKIP. Results: For the first time, this study confirmed through qPCR that PLCβ1 gene expression is lower in human GBM patient samples. Moreover, PLCβ1 gene expression inversely correlates with pathological grades of glioma; it decreases as glioma grades increases or worsens. Silencing PLCβ1 in U87MG GBM cells produces a dual impact in GBM by participating in both pro-tumoral and anti-tumoral roles. PLCβ1 knockdown cells were observed to have more migratory abilities, increased cell to extracellular matrix (ECM) adhesion, transition from epithelial phenotype to mesenchymal phenotype through the upregulation of EMT transcription factors Twist1 and Slug, and mesenchymal marker, vimentin. On the other hand, p-Akt and p-mTOR protein expression were downregulated in PLCβ1 knockdown cells. Thus, the oncogenic pathway PI3K/Akt/mTOR pathway is inhibited during PLCβ1 knockdown. Consistently, cell viability in PLCβ1 knockdown cells were significantly decreased compared to controls. As for SKIP, this study demonstrated that about 48% of SKIP colocalizes with nuclear PtdIns(4,5)P2 to nuclear speckles and that SKIP knockdown alters nuclear PtdIns(4,5)P2 in a cell-type dependent manner. In addition, SKIP silencing increased tumor volume and weight in xenografts than controls by reducing apoptosis and increasing viability. All in all, these data confirm that PLCβ1 and SKIP are involved in GBM pathology and a complete understanding of their roles in GBM may be beneficial.

Evaluation of the theranostic use of miRNAs in correlation to the radiopharmaceutical 64CuCl2 in glioblastoma

B:Glioblastoma multiforme(GBM) is one of the most prevalent and aggressive malignant primary brain tumors in adult patients. 64CuCl2 is an innovative radiopharmaceutical investigated as theranostic agent in GBM patients. The therapeutic scheme is still under evaluation, therefore the research focused on the possibility of radioresistance development. The actors responsible for modulating radioresistance could be miRNAs, thus their potential use was investigated both in radioresistant cell lines and in GBM patients plasma samples. M:Radioresistant cell lines were generated by exposing U87MG, U373MG lines to increasing doses of radiation for 32 weeks. Cell membrane permeability alterations and DNA damage were assessed to characterize the lines. Moreover, 64Cu cell incorporation and subcellular distribution were investigated measuring gamma-radiation emission. miRNA expression was evaluated: in parental and radioresistant cell lines, both in cell pellet and media exosomes; in plasma samples of GBM patients using TaqMan Array MicroRNA Cards. R:Radioresistant lines exhibited reduction in membrane permeability and in DNA DSBs indicating the capability to skip the drug killing effect. Cell uptake assays showed internalization of 64Cu both in the sensitive and radioresistant lines. Radioresistant lines showed a different miRNA expression profile compared to the parental lines. 5 miRNAs were selected as possible biomarkers of response to treatment (miR-339-3p, miR-133b, miR-103a-3p, miR-32-5p, miR-335-5p) and 6 miRNAs as possible predictive biomarkers of response to treatment (let-7e-5p, miR-15a-5p, miR-29c-3p, miR-495, miR-146b-5p, miR-199a-5p). miR-32-5p was selected as possible molecule to be used to restore 64CuCl2 responsiveness in the radioresistant cell lines. C: This is the first study describing the development and characterization of 64CuCl2 radioresistant cell lines useful to implement the approach for dosimetric analysis to avoid radioresistance uprising. miRNAs could bring to a better understanding of 64CuCl2 treatment, becoming a useful tool both in detection of treatment response and both as molecule that could restore responsiveness to 64CuCl2 treatment.

The role of Phospholipases as novel potential modulators of aggressiveness in Glioblastoma

Glioblastoma is the most malignant brain tumor in adults. The standard care of treatment is tumor resection, radiotherapy, and chemotherapy. Despite these invasive therapeutic approaches, glioblastoma prognosis remains unchanged. Therefore, a better understanding of the molecular mechanisms driving tumor transformation is needed to uncover novel therapeutic strategies. Several studies have shown the significance of lipid signaling and phospholipases (PLCs) in the regulation of different mechanisms in the central nervous system as well as in glioblastoma pathogenesis. This work suggests a potential role of PLCβ1 in the maintenance of a less aggressive phenotype of the tumor. Indeed, it was demonstrated that PLCβ1 gene was relatively less expressed in glioblastoma patients compared to their healthy/low-grade counterparts. Moreover, PLCβ1 silencing, in both immortalized and primary cell lines, led to increased cell migration, invasion, proliferation, cell survival and induced the upregulation of mesenchymal markers and metalloproteinases. Moreover, PLCγ1, another abundant PLC isoform in the brain, has been identified as a key element for the aggressiveness of glioblastoma. Data collected on patients’ biopsies and engineered cell models, suggested a strong correlation between PLCγ1 expression level and the acquisition of a more aggressive tumor phenotype. Finally, this trend was further probed using patient-derived glioblastoma stem cells (GSCs), which are a specific tumor population that drives aggressiveness, resistance, and recurrence in glioblastoma. GSCs analysis on the transcriptomic profiles confirmed that PLCγ1 downregulation modulated positively the activation of pathways that negatively regulate cell motility and migration and led to a decreased expression of genes involved in cancer development and progression. Taken together, these data highlight the importance of further investigating phospholipases as potential prognostic biomarkers and targets in the development of new therapeutic strategies for glioblastoma.

“Clinical and biological role of adjuvant dendritic cells vaccination in newly glioblastoma patients”

Background. Glioblastoma (GBM) is the most common primary tumor of central nervous system and it has a poor prognosis. Standard first line treatment, which includes surgery followed by adjuvant radio-chemotherapy,produces only modest benefits to survival. The interest for immunotherapy in this field derives from the development of new drugs and effective therapies as immune-check points inhibitors, adoptive T-cell approaches or dendritic cell (DC) based vaccines or a combinations of these. GBM is described as a typical “immune-deserted” cancer exhibiting a number of systemic and environmental immunosuppressive factors. Considering the role of microenvironment, and above all the lower tumor load and depletion of immunosuppressive cells in GBM, our hypothesis is that DC vaccine may induce an immune response. Main aims and study design. The main aim of this project is to study the role of immune system in GBM, including identification of potential prognostic and predictive markers of outcome and response to dendritic cell vaccine. Firstly, we performed a retrospective analysis on blood samples. Then, we analyzed the immuno-component in tissues samples of enrolled patients; and compared that with blood results. Then, the last part of the project is based on a prospective clinical trial on patients enrolled in DC-based vaccination produced at IRST Cell Factory and actually used for patients with melanoma and other tumors. The enrollment is still ongoing. Expected results. The project will i) develop an immune-panel of prognostic and predictive markers to help clinicians to improve the therapeutic strategy for GBM patients; ii) provide preliminary results on the effectiveness of immunotherapy on GBM patients.

La metilazione del DNA come meccanismo di regolazione dell'espressione genica

La regolazione dell’espressione genica è un processo molto complesso e finemente controllato da fattori multipli, tra i quali quelli epigenetici hanno richiamato l’attenzione nell’ultima decade. I meccanismi di regolazione epigenetica comprendono la metilazione del DNA a livello delle isole CpG nella regione del promotore del gene e le modifiche istoniche post-traduzionali, quali acetilazioni e metilazioni. Questa serie di elementi di regolazione concorre a determinare uno stato di impacchettamento della cromatina più o meno rilassato, che influenzerà la trascrizione di geni critici, per esempio nello sviluppo o nelle neoplasie. Gli ambiti nei quali lo studio del profilo epigenetico ha assunto maggiore rilievo sono effettivamente quello oncologico e quello del differenziamento di cellule staminali, due contesti nei quali si è svolto il mio programma di Dottorato, nel quale ho seguito in parallelo più progetti presentati nella tesi in modo indipendente. La ricerca in campo tumorale è centrata sull’indagine di nuovi marcatori e sull’individuazione di profili epigenetici specifici per un determinato tumore che possano aiutare la diagnostica precoce, la classificazione e la sorveglianza dell’evoluzione clinica della neoplasia. In questo contesto si inserisce il progetto finalizzato alla costruzione di quadri associativi di metilazione in due tumori cerebrali, il glioblastoma (GBM) e l’oligodendroglioma (ODG). La casistica di GBM e di ODG in dotazione è stata valutata dal punto di vista della metilazione dei promotori di geni (MGMT, EMP3,..) con funzioni oncosoppressive e trovati ipermetilati anche in altri tumori o localizzati in regioni citologicamente instabili, per poter correlare questi dati con la risposta terapeutica nel caso del GBM o con i dati di perdita di eterozigosità (LOH) 1p19q nel caso dell’ODG. Parallelamente all’individuazione di marcatori epigenetici in ambito oncologico, la ricerca si sta muovendo anche nell’indagine di nuove potenziali terapie farmacologiche antitumorali su base epigenetica. In questo contesto, con lo scopo di approfondire le relazioni tra i meccanismi alla base della regolazione epigenetica, ci si è riproposti di valutare la correlazione tra il meccanismo di metilazione/demetilazione del DNA e quello di acetilazione/deacetilazione istonica e la loro vicendevole influenza nel determinare silenziamento genico piuttosto che riattivazione dell’espressione di geni ipermetilati. Sono stati usati farmaci epigenetici demetilanti, quali Azacitidina e Decitabina, inibitori della istone deacetilasi, quali la Tricostatina A, e inibitori della via di sintesi di molecole, le poliammine, coinvolte nella regolazione dell’espressione genica con modalità ancora da precisare in modo definitivo. Sebbene i meccanismi di regolazione epigenetica vengano studiati per lo più nel cancro, a causa delle gravi conseguenze che una loro disregolazione porta in termini di silenziamento di geni oncosoppressori, essi sono implicati fisiologicamente anche nel differenziamento di cellule staminali. Gli ultimi due progetti trattati nella tesi si contestualizzano in questo ambito. In particolare viene presentata la messa a punto di una metodologia di immunoprecipitazione sequenziale della cromatina finalizzata all’individuazione di due modificazioni istoniche associate alla stessa regione di DNA. Le modifiche hanno riguardato i marcatori rappresenatativi di cromatina trascrizionalmente repressa H3K27me3 (trimetilazione della Lys27 dell’istone H3) e di cromatina trascrizionalmente attiva H3K24me2 (dimetilazione della Lys4 dell’istone H3) che definiscono i domini detti bivalenti, associati a geni che codificano per fattori di trascrizione che regolano lo sviluppo in cellule embrionali staminali, mantenendoli pronti per un veloce indirizzamento verso l’ attivazione trascrizionale. Il ruolo che la regolazione epigenetica svolge durante il differenziamento di cellule staminali non è ancora noto con precisione. È chiaro però che la memoria della linea cellulare verso la quale si differenzia una cellula staminale adulta, implica l’utilizzo di modifiche epigenetiche, quali la metilazione del DNA e correlati pattern di metilazione e acetilazione istonica. L’ultimo progetto, trattato, è stato finalizzato a verificare il coinvolgimento dell’epigenetica e in particolare della metilazione dei promotori di fattori trascrizionali precocemente attivati durante il differenziamento verso il fenotipo muscolare cardiaco di cellule staminali umane derivate da tessuto adiposo (ADSCs).

Studio di marcatori immunoistochimici, analisi FISH e ruolo dei microRNA nelle neoplasie gliali di basso e di alto grado

Gliomas are the most common primary brain tumours. Despite advances in surgical techniques, postoperative supportive care, radiation and adjuvant systemic therapy, the life expectancy of patients with high grade glioma has remained essentially poor. Furthermore differential diagnosis among astrocytomas, oligodendrogliomas and oligoastrocytomas is very challenging and subject to inter-observer variability. The purpose of the research was: 1) to investigate a series of high grade and low grade gliomas at gene and protein (immunohistochemistry) levels to disclose possible genetic portraits of malignancy; 2) to verify the utility of Nogo-A, Olig-2 and synaptophysin in providing a correct histological diagnosis of oligodendroglioma and to investigate a possible complementary role in selecting the best areas suitable for detecting 1p/19q codeletion using FISH analysis; 3) to study the role of microRNA in high grade gliomas. In order to obtain these goals large series of brain tumors were studied with DNA microarrays, immunohistochemistry and RT-PCR The results demonstrated that: - Overexpression of IGFBP-2 and CDC20 is highly related to glioblastomas and their immunopositivity can be useful for the identification of glioblastoma in small biopsies. - Nogo-A is the most useful and specific marker in differentiating oigodendrogliomas from other gliomas. Furthermore, using a Nogo-A driven FISH analysis, it is possible to identify a larger number of 1p19q codeletions in gliomas. - microRNAs can be studied in paraffin embedded tissues better than in fresh tissues. A series of six microRNA, significatively deregulated in glioblastomas, may represent a genetic signature with prognostic and predictive value and could constitute candidates for novel anti-cancer therapeutics.

MicroRNAs expression analysis in high grade gliomas

Several biomarkers had been proposed as useful parameters to better define the prognosis or to delineate new target therapy strategies for glioblastoma (GBM) patients. MicroRNAs could represent interesting molecules, for their role in tumorigenesis and cancer progression and for their specific tissue expression. Although many studies have tried to identify a specific microRNAs signature for glioblastoma, by now an exhaustive GBM microRNAs profile is far to be well defined. In this work we set up a real-time qPCR, based on LNA primers, to investigate the expression of 19 microRNAs in brain tumors, focusing our attention on GBMs. MiRNAs expression in 30 GBM paired FFPE-Fresh/Frozen samples was firstly analyzed. The good correlation obtained comparing miRNAs results confirmed the feasibility of performing miRNAs analysis starting from FFPE tissues. This leads to many advantages, as a good disposal of archival tumor and normal brain specimens and the possibility to verify the percentage of tumor cells in the analyzed sample. In the second part we compared 3 non-neoplastic brain references to use as control in miRNAs analysis. Normal adjacent the tumor, epileptic specimens and a commercial total RNA were analyzed for miRNAs expression and results showed that different non-neoplastic controls could lead to important discrepancies in GBM miRNAs profiles. Analyzing 50 FFPE GBMs using all 3 non-neoplastic references, we defined a putative GBM miRNAs signature: mir-10b, miR-21 and miR-27a resulted upregulated, while miR-7, miR-9, miR-26a, miR-31, miR-101, miR-137, miR-222 and miR-330 were downregulated. Comparing miRNAs expression among GBM group and gliomas of grade I, II and III, we obtained 3 miRNAs (miR-10b, mir-34a and miR-101) showing a different regulation status between high grade and low grade gliomas. Intriguingly, miR-10b was upregulated in high grade and significantly downregulated in low grade gliomas, suggesting that could be a candidate for a GBM target therapy.

Virus oncogeni a dna in tumori umani: studio delle infezioni da papillomavirus e poliomavirus in neoplasie di diversa origine.

I virus tumorali inducono oncogenesi nel loro ospite naturale o in sistemi animali sperimentali, manipolando diverse vie cellulari. Ad oggi, sono stati identificati sette virus capaci di causare specifici tumori umani. Inoltre HPV, JCV ed SV40, sono stati associati con un grande numero di tumori umani in sedi corporee non convenzionali, ma, nonostante molti anni di ricerca, nessuna eziologia virale è stata ancora confermata. Lo scopo di questo studio è stato di valutare la presenza ed il significato sia di JCV ed SV40 in tumori ossei umani, e di HPV nel carcinoma della mammella (BC), galattoforectomie (GF), secrezioni mammarie patologiche (ND) e glioblastoma multiforme (GBM). Tecniche di biologia molecolare sono state impiegate per esaminare campioni di tessuto tumorale di 70 tumori ossei (20 osteosarcomi [OS], 20 tumori a cellule giganti [TCG], 30 condrosarcomi [CS]), 168 BCs , 30 GFs, 59 GBM e 30 campioni di ND. Il genoma di SV40 e JCV è stato trovato nel 70% dei CS + 20% degli OS, e nel 13% dei CS +10% dei TCG, rispettivamente. Il DNA di HPV è stato rilevato nel 30% dei pazienti con BC, nel 27% dei campioni GF e nel 13% dei NDs. HPV16 è stato il genotipo maggiormente osservato in tutti questi campioni, seguito da HPV18 e HPV35. Inoltre, il DNA di HPV è stato trovato nel 22% dei pazienti con GBM, in questo tumore HPV6 era il tipo più frequentemente rilevato, seguito da HPV16. L’ ISH ha mostrato che il DNA di HPV è situato all’interno di cellule tumorali mammarie e di GBM. I nostri risultati suggeriscono un possibile ruolo di JCV, SV40 e HPV in questi tumori, se non come induttori come promotori del processo neoplastico, tuttavia diversi criteri devono ancora essere soddisfatti prima di chiarirne il ruolo.

Development and characterisation of a neurogenic model of brain cancer

Primary glioblastoma (GB), the most common and aggressive adult brain tumour, is refractory to conventional therapies and characterised by poor prognosis. GB displays striking cellular heterogeneity, with a sub-population, called Glioblastoma Stem Cells (GSCs), intrinsically resistant to therapy, hence the high rate of recurrence. Alterations of the tumour suppressor gene PTEN are prevalent in primary GBM, resulting in the inhibition of the polarity protein Lgl1 due to aPKC hyperactivation. Dysregulation of this molecular axis is one of the mechanisms involved in GSC maintenance. After demonstrating that the PTEN/aPKC/Lgl axis is conserved in Drosophila, I deregulated it in different cells populations of the nervous system in order to individuate the cells at the root of neurogenic brain cancers. This analysis identified the type II neuroblasts (NBs) as the most sensitive to alterations of this molecular axis. Type II NBs are a sub-population of Drosophila stem cells displaying a lineage similar to that of the mammalian neural stem cells. Following aPKC activation in these stem cells, I obtained an adult brain cancer model in Drosophila that summarises many phenotypic traits of human brain tumours. Fly tumours are indeed characterised by accumulation of highly proliferative immature cells and keep growing in the adult leading the affected animals to premature death. With the aim to understand the role of cell polarity disruption in this tumorigenic process I carried out a molecular characterisation and transcriptome analysis of brain cancers from our fly model. In summary, the model I built and partially characterised in this thesis work may help deepen our knowledge on human brain cancers by investigating many different aspects of this complicate disease.