Isabella Monia Montagner

PSMA-Specific CAR-Engineered T Cells Eradicate Disseminated Prostate Cancer in Preclinical Models

Immunology-based interventions have been proposed as a promising curative chance to effectively attack postoperative minimal residual disease and distant metastatic localizations of prostate tumors. We developed a chimeric antigen receptor (CAR) construct targeting the human prostate-specific membrane antigen (hPSMA), based on a novel and high affinity specific mAb. As a transfer method, we employed last-generation lentiviral vectors (LV) carrying a synthetic bidirectional promoter capable of robust and coordinated expression of the CAR molecule, and a bioluminescent reporter gene to allow the tracking of transgenic T cells after in vivo adoptive transfer. Overall, we demonstrated that CAR-expressing LV efficiently transduced short-term activated PBMC, which in turn were readily stimulated to produce cytokines and to exert a relevant cytotoxic activity by engagement with PSMA+ prostate tumor cells. Upon in vivo transfer in tumor-bearing mice, CAR-transduced T cells were capable to completely eradicate a disseminated neoplasia in the majority of treated animals, thus supporting the translation of such approach in the clinical setting.

Paclitaxel-hyaluronan hydrosoluble bioconjugate: Mechanism of action in human bladder cancer cell lines ☆

OBJECTIVES A previously described hydrosoluble paclitaxel-hyaluronan bioconjugate appears particularly well suited for treatment of superficial bladder cancer because of its in vitro cytotoxic profile against urothelial carcinoma (UC) cell lines and in vivo biocompatibility. The aim of this work was to assess the mechanism of action of the bioconjugate in UC cells. MATERIALS AND METHODS Expression of CD44 and RHAMM hyaluronan-binding receptors in RT-4 and RT-112/84 UC cell lines, interaction of fluorochrome-labeled bioconjugate with tumor cells, CD44 modulation upon incubation with the compound or free hyaluronan, and caspase activation were assessed by flow cytometry. Cytotoxicity was studied by the MTT assay. Analysis of bioconjugate intracellular localization and effects on β-tubulin organization was carried out by confocal microscopy. RESULTS The paclitaxel-hyaluronan bioconjugate bound to UC tumor cells entered intracellular compartments through a saturable and energy-dependent mechanism that involved CD44, as assessed by blocking with specific antibody. Upon internalization, the bioconjugate accumulated into lysosomes where the esteric bond between paclitaxel and the hyaluronan moiety was cleaved, leading to cytoplasmic diffusion of the free drug, caspase activation, and disruption of the β-tubulin microtubular mesh with subsequent cell death. CONCLUSIONS Conjugation of paclitaxel to hyaluronan results in a new chemical entity, characterized by selective targeting to polymer receptors on plasma membrane and cell entry through receptor-mediated endocytosis, followed by lysosomal accumulation. Ultimately, the active molecule is released, fully preserving the cytotoxic potential and profile of clinically used free paclitaxel.

Design, synthesis and evaluation of biotin decorated inulin-based polymeric micelles as long-circulating nanocarriers for targeted drug delivery

Here, long-circulating behaviors of Inulin-based nanomicelles are demonstrated for the first time in vivo. We show the synthesis and evaluation of biotin (BIO)-decorated polymeric INVITE micelles constituted of substances of natural origin, Inulin (INU) and Vitamin E (VITE), as long-circulating carriers for receptor-mediated targeted drug delivery. The resulting INVITE or INVITE-BIO micelles, nanometrically sized, did not reveal any cytotoxicity after 24h of incubation with Caco-2 cells. Moreover, in vitro studies on Caco-2 cells monolayers indicated that the transport of INVITE-BIO micelles was faster than surface unmodified INVITE micelles. In vivo optical imaging studies evidenced that, upon intravenous administration, INVITE-BIO micelles were quantitatively present in the body up to 48h. Instead, after oral administration, the micelles were not found in the systemic circulation but eliminated with the normal intestinal content. In conclusion, INVITE-BIO micelles may enhance drug accumulation in tumor-cells over-expressing the receptor for biotin through receptor mediated endocytosis.

Rational design of polyarginine nanocapsules intended to help peptides overcoming intestinal barriers

The aim of this work was to rationally design and characterize nanocapsules (NCs) composed of an oily core and a polyarginine (PARG) shell, intended for oral peptide delivery. The cationic polyaminoacid, PARG, and the oily core components were selected based on their penetration enhancing properties. Insulin was adopted as a model peptide to assess the performance of the NCs. After screening numerous formulation variables, including different oils and surfactants, we defined a composition consisting of oleic acid, sodium deoxycholate (SDC) and Span 80. This selected NCs composition, produced by the solvent displacement technique, exhibited the following key features: (i) an average size of 180nm and a low polydispersity (0.1), (ii) a high insulin association efficacy (80-90% AE), (iii) a good colloidal stability upon incubation in simulated intestinal fluids (SIF, FaSSIF-V2, FeSSIF-V2), and (iv) the capacity to control the release of the associated insulin for >4h. Furthermore, using the Caco-2 model cell line, PARG nanocapsules were able to interact with the enterocytes, and reversibly modify the TEER of the monolayer. Both cell adhesion and membrane permeabilization could account for the pronounced transport of the NCs-associated insulin (3.54%). This improved interaction was also visualized by confocal fluorescent microscopy following oral administration of PARG nanocapsulesto mice. Finally, in vivo efficacy studies performed in normoglycemic rats showed a significant decrease in their plasma glucose levels after treatment. In conclusion, here we disclose key formulation elements for making possible the oral administration of peptides.

Peritoneal Tumor Carcinomatosis: Pharmacological Targeting with Hyaluronan-Based Bioconjugates Overcomes Therapeutic Indications of Current Drugs

Peritoneal carcinomatosis still lacks reliable therapeutic options. We aimed at testing a drug delivery strategy allowing a controlled release of cytotoxic molecules and selective targeting of tumor cells. We comparatively assessed the efficacy of a loco-regional intraperitoneal treatment in immunocompromised mice with bioconjugates formed by chemical linking of paclitaxel or SN-38 to hyaluronan, against three models of peritoneal carcinomatosis derived from human colorectal, gastric and esophageal tumor cell xenografts. In vitro, bioconjugates were selectively internalized through mechanisms largely dependent on interaction with the CD44 receptor and caveolin-mediated endocytosis, which led to accumulation of compounds into lysosomes of tumor cells. Moreover, they inhibited tumor growth comparably to free drugs. In vivo, efficacy of bioconjugates or free drugs against luciferase-transduced tumor cells was assessed by bioluminescence optical imaging, and by recording mice survival. The intraperitoneal administration of bioconjugates in tumor-bearing mice exerted overlapping or improved therapeutic efficacy compared with unconjugated drugs. Overall, drug conjugation to hyaluronan significantly improved the profiles of in vivo tolerability and widened the field of application of existing drugs, over their formal approval or current use. Therefore, this approach can be envisaged as a promising therapeutic strategy for loco-regional treatment of peritoneal carcinomatosis.

A BARF1-specific mAb as a new immunotherapeutic tool for the management of EBV-related tumors

ABSTRACT The use of monoclonal antibodies (mAb) for the diagnosis and treatment of malignancies is acquiring an increasing clinical importance, thanks to their specificity, efficacy and relative easiness of use. However, in the context of Epstein-Barr virus (EBV)-related malignancies, only cancers of B-cell origin can benefit from therapeutic mAb targeting specific B-cell lineage antigens. To overcome this limitation, we generated a new mAb specific for BARF1, an EBV-encoded protein with transforming and immune-modulating properties. BARF1 is expressed as a latent protein in nasopharyngeal (NPC) and gastric carcinoma (GC), and also in neoplastic B cells mainly upon lytic cycle induction, thus representing a potential target for all EBV-related malignancies. Considering that BARF1 is largely but not exclusively secreted, the BARF1 mAb was selected on the basis of its ability to bind a domain of the protein retained at the cell surface of tumor cells. In vitro, the newly generated mAb recognized the target molecule in its native conformation, and was highly effective in mediating both ADCC and CDC against BARF1-positive tumor cells. In vivo, biodistribution analysis in mice engrafted with BARF1-positive and -negative tumor cells confirmed its high specificity for the target. More importantly, the mAb disclosed a relevant antitumor potential in preclinical models of NPC and lymphoma, as evaluated in terms of both reduction of tumor masses and long-term survival. Taken together, these data not only confirm BARF1 as a promising target for immunotherapeutic interventions, but also pave the way for a successful translation of this new mAb to the clinical use.

A site-selective hyaluronan-interferonα2a conjugate for the treatment of ovarian cancer

While interferon alpha (IFNα) is used in several viral and cancer contexts, its efficacy against ovarian cancer (OC) is far from being incontrovertibly demonstrated and, more importantly, is hindered by heavy systemic side effects. To overcome these issues, here we propose a strategy that allows a targeted delivery of the cytokine, by conjugating IFNα2a with an aldehyde-modified form of hyaluronic acid (HA). The resulting HA-IFNα2a bioconjugate was biochemically and biologically characterized. The conjugation with HA did not substantially modified both the antiviral function and the anti-proliferative activity of the cytokine. Moreover, the induction of STAT1 phosphorylation and of a specific gene expression signature in different targets was retained. In vivo optical imaging biodistribution showed that the i.p.-injected HA-IFNα2a persisted into the peritoneal cavity longer than IFNα2a without being toxic for intraperitoneal organs, thus potentially enhancing the loco-regional therapeutic effect. Indeed, in OC xenograft mouse models bioconjugate significantly improved survival as compared to the free cytokine. Overall, HA-IFNα2a bioconjugate disclosed an improved anticancer efficacy, and can be envisaged as a promising loco-regional treatment for OC.

Cell-autonomous and cell non-autonomous downregulation of tumor suppressor DAB2IP by microRNA-149-3p promotes aggressiveness of cancer cells

The tumor suppressor DAB2IP contributes to modulate the network of information established between cancer cells and tumor microenvironment. Epigenetic and post-transcriptional inactivation of this protein is commonly observed in multiple human malignancies, and can potentially favor progression of tumors driven by a variety of genetic mutations. Performing a high-throughput screening of a large collection of human microRNA mimics, we identified miR-149-3p as a negative post-transcriptional modulator of DAB2IP. By efficiently downregulating DAB2IP, this miRNA enhances cancer cell motility and invasiveness, facilitating activation of NF-kB signaling and promoting expression of pro-inflammatory and pro-angiogenic factors. In addition, we found that miR-149-3p secreted by prostate cancer cells induces DAB2IP downregulation in recipient vascular endothelial cells, stimulating their proliferation and motility, thus potentially remodeling the tumor microenvironment. Finally, we found that inhibition of endogenous miR-149-3p restores DAB2IP activity and efficiently reduces tumor growth and dissemination of malignant cells. These observations suggest that miR-149-3p can promote cancer progression via coordinated inhibition of DAB2IP in tumor cells and in stromal cells.

Spatial resolution performance and object detection improvement with a multiple-wavelength NIR light transmission scanner

A multiple-wavelength near-infrared (NIR) imaging device has been constructed. The scanner utilizes transmitted through the objects NIR light at five different wavelengths in the interval of 900nm–1600nm. The scanning is realized by a consecutive positioning of Hamamatsu G9203–256D InGaAs linear image sensor sliding close to the scanned object and results in a set of five objects images. The scanned region has a rectangular shape with dimensions of 50mm × 80mm. A system of polarizers ensures scanning of the objects in polarized NIR light as well. The number of object images obtained at different wavelengths and at different angles of the transmitted NIR light makes possible the application of a multivariate image analysis (MIA) in order to reveal tissue objects whose NIR light absorption exhibits slight deviations from the rest of the media. In this article we present results from the spatial resolution measurements conducted with the scanner as well as a spectral analysis of the transmittance of NIR in some mice tissues. A multivariate image analysis has been conducted on NIR images of mice tumor tissues taken at different wavelengths. The resulted images from the MIA projection back compare well with the observations from alternative methods.