Novel Mouse Mammary Cell Lines for \u3cem\u3ein vivo\u3c/em\u3e Bioluminescence Imaging (BLI) of Bone Metastasis

Background Tumor cell lines that can be tracked in vivo during tumorigenesis and metastasis provide vital tools for studying the specific cellular mechanisms that mediate these processes as well as investigating therapeutic targets to inhibit them. The goal of this study was to engineer imageable mouse mammary tumor cell lines with discrete propensities to metastasize to bone in vivo. Two novel luciferase expressing cell lines were developed and characterized for use in the study of breast cancer metastasis to bone in a syngeneic mouse model. Results The 4T1.2 luc3 and 66c14 luc2 cell lines were shown to have high levels of bioluminescence intensity in vitro and in vivo after orthotopic injection into mouse mammary fat pads. The 4T1.2 luc3 cell line was found to closely model the sites of metastases seen in human patients including lung, liver, and bone. Specifically, 4T1.2 luc3 cells demonstrated a high incidence of metastasis to spine, with an ex-vivo BLI intensity three orders of magnitude above the commercially available 4T1 luc2 cells. 66c14 luc2 cells also demonstrated metastasis to spine, which was lower than that of 4T1.2 luc3 cells but higher than 4T1 luc2 cells, in addition to previously unreported metastases in the liver. High osteolytic activity of the 4T1.2 luc3 cells in vivo in the bone microenvironment was also detected. Conclusions The engineered 4T1.2 luc3 and 66c14 luc2 cell lines described in this study are valuable tools for studying the cellular events moderating the metastasis of breast tumor cells to bone

Oncostatin M Promotes Mammary Tumor Metastasis to Bone and Osteolytic Bone Degradation

Oncostatin M (OSM) is an interleukin-6 (IL-6) family cytokine that has been implicated in a number of biological processes including inflammation, hematopoiesis, immune responses, development, and bone homeostasis. Recent evidence suggests that OSM may promote breast tumor invasion and metastasis. We investigated the role of OSM in the formation of bone metastases in vivo using the 4T1.2 mouse mammary tumor model in which OSM expression was knocked down using shRNA (4T1.2-OSM). 4T1.2-OSM cells were injected orthotopically into Balb/c mice, resulting in a greater than 97% decrease in spontaneous metastasis to bone compared to control cells. Intratibial injection of these same 4T1.2-OSM cells also dramatically reduced the osteolytic destruction of trabecular bone volume compared to control cells. Furthermore, in a tumor resection model, mice bearing 4T1.2-OSM tumors showed an increase in survival by a median of 10 days. To investigate the specific cellular mechanisms important for OSM-induced osteolytic metastasis to bone, an in vitro model was developed using the RAW 264.7 preosteoclast cell line co-cultured with 4T1.2 mouse mammary tumor cells. Treatment of co-cultures with OSM resulted in a 3-fold induction of osteoclastogenesis using the TRAP assay. We identified several tumor cell–induced factors including vascular endothelial growth factor, IL-6, and a previously uncharacterized OSM-regulated bone metastasis factor, amphiregulin (AREG), which increased osteoclast differentiation by 4.5-fold. In addition, pretreatment of co-cultures with an anti-AREG neutralizing antibody completely reversed OSM-induced osteoclastogenesis. Our results suggest that one mechanism for OSM-induced osteoclast differentiation is via an AREG autocrine loop, resulting in decreased osteoprotegerin secretion by the 4T1.2 cells. These data provide evidence that OSM might be an important therapeutic target for the prevention of breast cancer metastasis to bone

Novel mouse mammary cell lines for in vivo bioluminescence imaging (BLI) of bone metastasis

Abstract Background Tumor cell lines that can be tracked in vivo during tumorigenesis and metastasis provide vital tools for studying the specific cellular mechanisms that mediate these processes as well as investigating therapeutic targets to inhibit them. The goal of this study was to engineer imageable mouse mammary tumor cell lines with discrete propensities to metastasize to bone in vivo. Two novel luciferase expressing cell lines were developed and characterized for use in the study of breast cancer metastasis to bone in a syngeneic mouse model. Results The 4 T1.2 luc3 and 66c14 luc2 cell lines were shown to have high levels of bioluminescence intensity in vitro and in vivo after orthotopic injection into mouse mammary fat pads. The 4 T1.2 luc3 cell line was found to closely model the sites of metastases seen in human patients including lung, liver, and bone. Specifically, 4 T1.2 luc3 cells demonstrated a high incidence of metastasis to spine, with an ex-vivo BLI intensity three orders of magnitude above the commercially available 4 T1 luc2 cells. 66c14 luc2 cells also demonstrated metastasis to spine, which was lower than that of 4 T1.2 luc3 cells but higher than 4 T1 luc2 cells, in addition to previously unreported metastases in the liver. High osteolytic activity of the 4 T1.2 luc3 cells in vivo in the bone microenvironment was also detected. Conclusions The engineered 4 T1.2 luc3 and 66c14 luc2 cell lines described in this study are valuable tools for studying the cellular events moderating the metastasis of breast tumor cells to bone.</p

Studies of responsive properties of poly(n-isopropylacrylamide-co-methacrylic acid) nanoparticles for targeted drug delivery

grantor: University of TorontoPoly(N-isopropylacrylamide-co-methacrylic acid) P(NIPAm/MAA) nanoparticles were investigated as potential targetable systems for intravenous drug delivery. The responsive properties of P(NIPAm/MAA) nanoparticles have been characterized using dynamic light scattering (DLS) and responsive adhesion techniques. The hydrodynamic diameter of the nanoparticles decreased with increasing temperature of the aqueous medium. Particle size distributions were Gaussian and relatively monodisperse (GSD $<$ 20% of the mean diameter). The volume phase transition temperature, T\sb{\rm c}, of the nanoparticles was sensitive to the state of ionization of surface groups. T\sb{\rm c} increased with increasing pH and decreasing ionic strength of the suspending buffers. The particle concentration of nanoparticles per unit volume was calculated by turbidimetry using Mie theory. The surface hydrophobicity of the nanoparticles was evaluated by partitioning of Rose Bengal on particle surfaces, hydrophobic interaction chromatography (HIC), and partitioning of nanoparticles in PEG/Dextran systems. The surface hydrophobicity of the nanoparticles was found to be greater at 40\sp\circC than at 25\sp\circC by each method. The pH dependence of the partitioning of nanoparticles suggested a cross-over from a steric to a charge stabilization mechanism when the temperature was raised above T\sb{\rm c}. Conductometric titration of the nanoparticles suggests that the majority of charges are due to carboxylate residues. The zeta-potential of nanoparticles showed significant levels of surface charge that increased with increasing MAA content. Neither opsonized nor unopsonized P(NIPAm/MAA) nanoparticles stimulated the consumption of oxygen by human neutrophils suggesting the absence of phagocytic cell response whereas polystyrene latexes of similar size and surface charge stimulated increased oxygen consumption by the neutrophils.M.Sc

Withaferin A Inhibits Prostate Carcinogenesis in a PTEN-deficient Mouse Model of Prostate Cancer

We recently demonstrated that AKT activation plays a role in prostate cancer progression and inhibits the pro-apoptotic function of FOXO3a and Par-4. AKT inhibition and Par-4 induction suppressed prostate cancer progression in preclinical models. Here, we investigate the chemopreventive effect of the phytonutrient Withaferin A (WA) on AKT-driven prostate tumorigenesis in a Pten conditional knockout (Pten-KO) mouse model of prostate cancer. Oral WA treatment was carried out at two different doses (3 and 5 mg/kg) and compared to vehicle over 45 weeks. Oral administration of WA for 45 weeks effectively inhibited primary tumor growth in comparison to vehicle controls. Pathological analysis showed the complete absence of metastatic lesions in organs from WA-treated mice, whereas discrete metastasis to the lungs was observed in control tumors. Immunohistochemical analysis revealed the down-regulation of pAKT expression and epithelial-to-mesenchymal transition markers, such as β-catenin and N-cadherin, in WA-treated tumors in comparison to controls. This result corroborates our previous findings from both cell culture and xenograft models of prostate cancer. Our findings demonstrate that the daily administration of a phytonutrient that targets AKT activation provides a safe and effective treatment for prostate cancer in a mouse model with strong potential for translation to human disease