Methionine aminopeptidase 2 as a potential target in pancreatic ductal adenocarcinoma.

Pancreatic ductal adenocarcinoma (PDA) is an aggressive metastatic cancer with a very low survival rate. This tumor is hypovascularized and characterized by severe hypoxic regions, yet these regions are not impeded by the oxidative stress in their microenvironment. PDA's high resilience raises the need to find new effective therapeutic targets. This study investigated the suitability of methionine aminopeptidase 2 (MetAp2), a metallopeptidase known to play an important role in tumor progression, as a new target for treating PDA. In our examination of patient-derived PDA tissues, we found that MetAp2 is highly expressed in metastatic regions compared with primary sites. At the cellular level, we found that the basal expression levels of MetAp2 in pancreatic cancer cells were higher than its levels in endothelial cells. Pancreatic cancer cells showed a significant suppression of proliferation in a dose-dependent manner upon exposure to TNP-470, a selective MetAp2 inhibitor. In addition, a significant reduction in glutathione (GSH) levels - known for its importance in alleviating oxidative stress - was detected in all treated cells, suggesting a possible anti-cancer activity mechanism that would be feasible for treating highly hypoxic PDA tumors. Furthermore, in an orthotopic pancreatic cancer murine model, systemic oral treatment with a MetAp2 inhibitor significantly reduced tumors' growth. Taken together, our findings indicate that MetAp2 enhances tumor sensitivity to hypoxia and may provide an effective target for treating hypoxic tumors with high expression levels of MetAp2.

Rapid Clearing for High Resolution 3D Imaging of Ex Vivo Pancreatic Cancer Spheroids.

The currently accepted imaging methods have been a central hurdle to imaging the finer details of tumor behavior in three-dimensional (3D) ex vivo multicellular culture models. In our search for an improved way of imaging tumor behavior in its physiological-like niche, we developed a simple, efficient, and straightforward procedure using standard reagents and imaging equipment that significantly enhanced 3D imaging up to a ~200-micron depth. We tested its efficacy on pancreatic spheroids, prototypes of high-density tissues that are difficult to image. We found we could both save time with this method and extract information about pancreatic tumor spheroids that previously was difficult to obtain. We were able to discern clear differences in the organization of pancreatic tumor spheroids generated from different origins, suggesting cell-specific, inherent, bottom-up organization with a correlation to the level of malignancy. We also examined the dynamic changes in the spheroids at predetermined time points, providing important information related to tissue morphogenesis and its metabolic state. Lastly, this process enabled us to assess a drug vehicle's potential to penetrate dense tumor tissue by improving our view of the inert particles' diffusion in the 3D spheroid. This clearing method, a simple procedure, can open the door to more accurate imaging and reveal more about cancer behavior.

Triangular correlation (TrC) between cancer aggressiveness, cell uptake capability, and cell deformability.

The malignancy potential is correlated with the mechanical deformability of the cancer cells. However, mechanical tests for clinical applications are limited. We present here a Triangular Correlation (TrC) between cell deformability, phagocytic capacity, and cancer aggressiveness, suggesting that phagocytic measurements can be a mechanical surrogate marker of malignancy. The TrC was proved in human prostate cancer cells with different malignancy potential, and in human bladder cancer and melanoma cells that were sorted into subpopulations based solely on their phagocytic capacity. The more phagocytic subpopulations showed elevated aggressiveness ex vivo and in vivo. The uptake potential was preserved, and differences in gene expression and in epigenetic signature were detected. In all cases, enhanced phagocytic and aggressiveness phenotypes were correlated with greater cell deformability and predicted by a computational model. Our multidisciplinary study provides the proof of concept that phagocytic measurements can be applied for cancer diagnostics and precision medicine.

Integrin α2ß1-Targeted Self-Assembled Nanocarriers for Tumor Bioimaging.

Recent developments in near-infrared (NIR) dyes and imaging modalities enable tumor fluorescent images in preclinical and clinical settings. However, NIR dyes have several drawbacks, and therefore, there is an unmet diagnostic need for NIR dye encapsulation in appropriate pharmaceutical nanocarriers with targeting abilities for the purpose of achieving effective diagnosis and image-guided surgeries. Because integrin receptors are established diagnostic targets, the cyclic Arg-Gly-Asp (RGD) peptides, recognizing the αVß3 integrin, have been extensively investigated for radiology and bioimaging of tumors. However, the Lys(Arg)-Thr-Ser [K(R)TS] cyclic peptides, selective for collagen receptors α1ß1/α2ß1 integrins, which are overexpressed in many tumors, were not yet investigated and therefore used here for tumor bioimaging with a unique α2ß1-integrin-targeted nanocarrier, encapsulating the indocyanine green NIR dye. We synthesized three kinds of peptides: two cyclic RTS peptides functional only in the cyclic conformation and a linear peptide lacking the cyclic cysteine constrained RTS loop. We used them for the preparation of integrin-targeted self-assembled nanocarriers (ITNCs), referred to as OF5 and OF27, and a nontargeted control nanocarrier, referred to as OF70. Their selective association was demonstrated with α2ß1 integrin expressing cell cultures and three-dimensional tumor spheroids and by competition with a α2ß1 selective disintegrin. Cytotoxicity experiments in vitro demonstrated the safety of the ITNCs. The targeting potential and the biodistribution of the ITNCs, applied intravenously in A431 tumor-bearing nude mice, were evaluated in vivo using NIR bioimaging. Time-dependent biodistributions indicated that the ITNC OF27 showed higher fluorescent signals in main tissues, with no cytotoxic effects to major organs, and presented higher accumulation in tumors. Cumulatively, these results highlight the potential of the ITNC OF27 as an optical and innovative pharmaceutical bioimaging system, suitable for integrin α2ß1 receptor in vivo tumor targeting and visualization in the NIR region.