Citation Details

Journal Article

4T1-luc2; Adenocarcinoma; Animals; Bioware; Breast Neoplasms; Cell Line, Tumor; Chemotaxis, Leukocyte; Cytotoxicity, Immunologic; Female; Humans; Immunotherapy, Adoptive; Indium Radioisotopes; Mammary Neoplasms, Experimental; Mice; Mice, Inbred BALB C; Mice, Knockout; Neoplasm Transplantation; Radiopharmaceuticals; Receptors, Antigen, T-Cell, gamma-delta; Spleen; Tissue Distribution; T-Lymphocyte Subsets; Tomography, Emission-Computed, Single-Photon; Transplantation, Heterologous; Transplantation, Isogeneic

In contrast to antigen-specific alphabeta-T cells (adaptive immune system), gammadelta-T cells can recognize and lyse malignantly transformed cells almost immediately upon encounter in a manner that does not require the recognition of tumor-specific antigens (innate immune system). Given the well-documented capacity of gammadelta-T cells to innately kill a variety of malignant cells, efforts are now actively underway to exploit the antitumor properties of gammadelta-T cells for clinical purposes. Here, we present for the first time preclinical in vivo mouse models of gammadelta-T cell-based immunotherapy directed against breast cancer. These studies were explicitly designed to approximate clinical situations in which adoptively transferred gammadelta-T cells would be employed therapeutically against breast cancer. Using radioisotope-labeled gammadelta-T cells, we first show that adoptively transferred gammadelta-T cells localize to breast tumors in a mouse model (4T1 mammary adenocarcinoma) of human breast cancer. Moreover, by using an antibody directed against the gammadelta-T cell receptor (TCR), we determined that localization of adoptively transferred gammadelta-T cells to tumor is a TCR-dependant process. Additionally, biodistribution studies revealed that adoptively transferred gammadelta-T cells traffic differently in tumor-bearing mice compared to healthy mice with fewer gammadelta-T cells localizing into the spleens of tumor-bearing mice. Finally, in both syngeneic (4T1) and xenogeneic (2Lmp) models of breast cancer, we demonstrate that adoptively transferred gammadelta-T cells are both effective against breast cancer and are otherwise well-tolerated by treated animals. These findings provide a strong preclinical rationale for using ex vivo expanded adoptively transferred gammadelta-T cells as a form of cell-based immunotherapy for the treatment of breast cancer. Additionally, these studies establish that clinically applicable methods for radiolabeling gammadelta-T cells allows for the tracking of adoptively transferred gammadelta-T cells in tumor-bearing hosts.

Journal Article

IntegriSense,, Animals; Diagnostic Imaging/*methods; Fluorescent Dyes/metabolism; Genes, Reporter; Neovascularization, Pathologic/*diagnosis; *Optical Phenomena

In recent years, molecular imaging gained significant importance in biomedical research. Optical imaging developed into a modality which enables the visualization and quantification of all kinds of cellular processes and cancerous cell growth in small animals. Novel gene reporter mice and cell lines and the development of targeted and cleavable fluorescent “smart” probes form a powerful imaging toolbox. The development of systems collecting tomographic bioluminescence and fluorescence data enabled even more spatial accuracy and more quantitative measurements. Here we describe various bioluminescent and fluorescent gene reporter models and probes that can be used to specifically image and quantify neovascularization or the angiogenic process itself.

Journal Article

AngioSense, Animals; Antineoplastic Agents/therapeutic use; Diagnostic Imaging/*methods; Female; Mammary Neoplasms, Animal/metabolism/pathology; Mice; Mice, Nude; Neoplasm Transplantation; Neovascularization, Pathologic/drug therapy/*pathology

In vivo angiogenesis assays provide more physiologically relevant information about tumor vascularization than in vitro studies because they take the complex interactions among cancer cells, endothelial cells, mural cells, and tumor stroma into consideration. Traditional microscopic assessment of vascular density conducted by immunostaining of tissue sections or by lectin angiogram visualization of tumor vessels is invasive and requires the sacrifice of tumor-bearing animals. Therefore, it prohibits longitudinal time-course observation in a single animal and requires a large number of animals at each time point to derive statistically-meaningful observations. Additionally, heterogenous behavior among different tumors will inevitably introduce individual biological variance that may obscure reliable interpretation of the results. While various artificial in vivo angiogenesis assays, such as the Matrigel implant assay, chick chorioallatoic membrane assay, and dorsal skin fold chamber assay have been developed and employed to more directly observe the progression of physiological angiogenesis, they can not appropriately assess tumor angiogenic progression or tumor vascular regression in response to therapeutic intervention. Here, we describe a noninvasive method and a detailed protocol that we have developed and optimized using the Olympus OV-100 in vivo imaging system for real-time high-resolution visualization and assessment of tumor angiogenesis and vascular response to anticancer therapies in live animals. We show that using this approach, tumor vessels can be monitored longitudinally through the whole vasculogenesis and angiogenesis process in the same mouse. Further, morphologic changes of the same vessel prior to and after drug treatments can be captured with microscopic high resolution. Moreover, the multichannel co-imaging capability of the OV-100 allows us to analyze and compare tumor vessel permeability before and after antiangiogenesis therapy by employing a near-infrared blood pool reagent, or by visualizing improved cytotoxic drug delivery upon tumor vessel normalization by using a fluorophore tagged drug. This noninvasive method can be readily applied to orthotopically transplanted breast cancer models as well as to subcutaneously-transplanted tumor models.

Journal Article

B16-F10-luc2, Melanoma, B16F10-luc2, IVIS

In-transit metastasis (ITM) is a unique manifestation of intralymphatic tumor dissemination, characterized by the presence of melanoma cells between the primary lesion and the draining regional lymph node basin that is clinically associated with poor prognosis. In this study, we aimed to establish an experimental animal model of melanoma ITM, as research progress in this field has been hampered by a lack of suitable experimental models. We reproduced melanoma ITM in a mouse hind limb by transplanting melanoma cells into the footpad of a mouse with lymphedema (LE). The tumor cells at the ITM site were highly proliferative, and mice with ITMs were more likely than control mice to develop distant lymph node and lung metastases. Peritumoral lymphatic vessels and tumor-associated blood vessels were increased in the primary tumor site of the LE mice. Our established ITM melanoma mouse model enabled us to clarify the molecular determinants and pathophysiology of ITM. This ITM model is also comparable to the unfavorable clinical behavior of melanoma ITM in humans and, moreover, underlined the importance of lymphangiogenic factors in the tumor dissemination through the lymphatic system.Journal of Investigative Dermatology advance online publication, 6 September 2012; doi:10.1038/jid.2012.274.

Journal Article

Animals; Anti-Infective Agents; Bacterial Adhesion; Biofilms; Bioware; Chromosomes, Bacterial; Colony Count, Microbial; Disease Models, Animal; Female; Mice; Mice, Inbred BALB C; Microbial Sensitivity Tests; Prostheses and Implants; pXen-5; Soft Tissue Infections; Staphylococcal Infections; Staphylococcus aureus; Xen29

Infection is the main cause of biomaterials-related failure. A simple technique to test in-vivo new antimicrobial and/or nonadhesive implant coatings is unavailable. Current in vitro methods for studying bacterial adhesion and growth on biomaterial surfaces lack the influence of the host immune system. Most in vivo methods to study biomaterials-related infections routinely involve implant-removal, preventing comprehensive longitudinal monitoring. In vivo imaging circumvents these drawbacks and is based on the use of noninvasive optical imaging of bioluminescent bacteria. Staphylococcus aureus Xen29 is genetically modified to be stably bioluminescent, by the introduction of a modified full lux operon onto its chromosome. Surgical meshes with adhering S. aureus Xen29 were implanted in mice and bacterial growth and spread into the surrounding tissue was monitored longitudinally from bioluminescence with a highly sensitive CCD camera. Distinct spatiotemporal bioluminescence patterns, extending beyond the mesh area into surrounding tissues were observed. After 10 days, the number of living organisms isolated from explanted meshes was found to correlate with bioluminescence prior to sacrifice of the animals. Therefore, it is concluded that in vivo imaging using bioluminescent bacteria is ideally suited to study antimicrobial coatings taking into account the host immune system. In addition, longitudinal monitoring of infection in one animal will significantly reduce the number of experiments and animals.