Differentiating effect of pamidronate on canine osteo‐sarcoma cell lines in vitro

Introduction: Pamidronate has been traditionally used to manage pathologic osteoclastic disorders. In addition to its effects on osteoclasts, pamidronate has also been demonstrated to promote phenotypic maturation and inhibition of proliferation in osteoblasts. Canine osteosarcoma (OSA) consists of malignant, undifferentiated osteoblasts. The objective of this study was to determine if micromolar concentrations of pamidronate could induce malignant osteoblastic differentiation as evaluated by an increase in alkaline phosphatase (ALP) activity and/or osteocalcin (OC) production, two specific markers of normal osteoblastic activity. Methods: Two canine OSA cell lines (HMPOS and COS 31) were used for all experiments. Cells were incubated for 48 or 72 hours with various pamidronate concentrations (0, 0.1, 1, 5, 10, and 20 μM). After incubation, the supernatants were sampled and the relative amounts of viable cells were determined with a cell proliferation assay (Cell Titer 96^® AQ_uous, Promega). An ALP detection kit (Starbright^®, Sigma^®) was used to measure the ALP activity and an ELISA (Osteocalcin EIA kit, Biomedical Technologies) was used to determine the concentration of osteocalcin in the supernatants. The ALP and osteocalcin values were corrected for the amount of viable cells. Results: Pamidronate induced a dose‐dependent reduction in the number of viable COS 31 and HMPOS cells at both 48 and 72 hours. A dose‐dependent elevation in ALP activity from baseline was observed. At 20 μM, a 2.3‐fold increase was observed for HMPOS at 72 hours, while a 1.43‐fold increase was observed for COS 31 at 72 hours. Very low level (less than 2 ng/ml) of osteocalcin pre‐ and post‐pamidronate treatment was detected for both COS 31 and HMPOS. Conclusion: The data suggests that pamidronate increases alkaline phosphatase activity in canine OSA cells in a dose‐dependent manner. However, cytotoxic assays are needed in order to accurately characterize any concurrent decrease in the number of viable cells. The potential differentiating effect of pamidronate on malignant osteoblasts provides an additional argument for its use in the palliative treatment of OSA.     

The effect of deracoxib and piroxicam on viability of canine osteosarcoma cells in vitro

Introduction:  Cyclooxygenase‐2 (COX‐2) inhibitors are being used increasingly in cancer therapy. Although the effects of COX‐2 inhibitors have been evaluated extensively in carcinomas, less is known about their effects in sarcomas. Since the majority of dogs with appendicular osteosarcoma (OSA) are treated for pain with a non‐steroidal anti‐inflammatory drug (some COX‐2 selective) prior to definitive treatment, it is important to determine the effects that commonly used NSAIDS have on tumor cell growth.
Methods:  Established canine osteosarcoma (POS, HMPOS and COS31) and canine fibroblast cell lines were maintained in culture under standard conditions. Cells were incubated with either deracoxib (1 uM to 500 uM) or piroxicam (1 uM to 1000 uM). Cell viability was assessed at 72 hours by cell counts and the MTT assay. The DNA fragmentation analysis was utilized to assess for apoptosis induction.
Results:  Deracoxib concentrations ≥100 uM and piroxicam concentrations ≥500 uM significantly reduced mean cell viability of all three OSA cell lines (lowest cell viability percentages 20% and 32%, respectively). Deracoxib concentrations ≥250 uM and piroxicam concentrations ≥500 uM also reduced viability of fibroblasts; however, the cell viability percent was reduced to only 54% and 68%, respectively, of the control value. Exposure of OSA cells to cytotoxic concentrations of deracoxib and piroxicam did not result in DNA fragmentation.
Conclusions:  Deracoxib and piroxicam demonstrated a cytotoxic effect on canine osteosarcoma cells. There was no evidence of apoptosis induction at the concentrations evaluated. Further investigation will need to be performed to determine whether either drug exhibits anti‐tumor effects in vivo .     

Expression and significance of p53, rb,p21/waf-1, p16/ink-4a,and PTEN tumor suppressors in canine melanoma

The role of tumor suppressor genes in the pathogenesis of canine melanoma is incompletely understood. The genes encoding the tumor suppressors p53, Rb, p21 (waf-1), p16 (ink-4a), and PTEN have been postulated to contribute to the pathogenesis of melanoma in humans and experimental animal models. To assess whether inactivation of these genes similarly contributes to the origin and progression of canine melanoma, we examined their expression in seven distinct canine melanoma cell lines and in 31 retrospective samples (representing 29 dogs) of spontaneous canine melanoma. Various patterns suggestive of loss of tumor suppressor function emerged in these cell lines. The most frequently observed abnormality was loss or significant reduction of p16 expression in six of seven cell lines and in 21 of 26 tumor samples. Loss or significant reduction of PTEN expression was seen in four of seven cell lines and in 13 of 27 tumor samples. Although p53 was detectable in all the cell lines and in 24 of 30 tumors, exclusion of p53 from the nuclear compartment was observed in each of the cell lines and in 18 of 25 tumor samples. These results indicate that loss of function of these tumor suppressor proteins is a common occurrence that may contribute to the origin of canine melanoma. In our sample population, abnormalities in the expression or localization of one or more tumor suppressor proteins occurred with similar frequency in malignant and benign tumors; thus, additional work is necessary to determine how these proteins may impact disease progression and response to therapy.     

PDGFs and PDGFRs in canine osteosarcoma: New targets for innovative therapeutic strategies in comparative oncology

Platelet derived growth factor receptor (PDGFR)α and PDGFRβ are tyrosine kinase receptors that are overexpressed in 70–80% of human osteosarcomas (OSAs) and may be suitable therapeutic targets for specific kinase inhibitors (TKIs). Canine OSA shows histopathological and clinical features similar to human OSA, and is considered an excellent model in comparative oncology. This study investigated PDGF-A, PDGF-B, PDGFRα and PDGFRβ expression in 33 canine OSA samples by immunohistochemistry and in seven primary canine OSA cell lines by Western blot and quantitative PCR analysis.Immunohistochemical data showed that PDGF-A and PDGF-B are expressed in 42% and 60% of the OSAs analysed, respectively, while PDGFRα and PDGFRβ were expressed in 78% and 81% of cases, respectively. Quantitative PCR data showed that all canine OSA cell lines overexpressed PDGFRα, while 6/7 overexpressed PDGFRβ and PDGF-A relative to a normal osteoblastic cell line. Moreover, in vitro treatment with a specific PDGFR inhibitor, AG1296, caused a dose- and time-dependent decrease in AKT phosphorylation. Collectively, these data show that PDGFRs/PDGFs are co-expressed in canine osteosarcomas, which suggests that an autocrine and/or paracrine loop is involved and that they play an important role in the aetiology of OSA. PDGFRs may be suitable targets for the treatment of canine OSA with a specific TKI.     

A novel small molecule Met inhibitor, PF2362376, exhibits biological activity against osteosarcoma

The receptor tyrosine kinase Met is dysregulated in several human cancers including osteosarcoma (OSA) in which overexpression is a negative prognostic indicator and enforced Met expression in normal osteoblasts leads to genomic instability and malignant transformation. Met is also known to be inappropriately expressed in canine OSA tumour samples and cell lines. The purpose of this study was to evaluate the potential utility of an orally bioavailable small molecule Met inhibitor, PF2362376, against canine OSA cell lines as a prelude to future clinical work. PF2362376 inhibited phosphorylation of Met, Gab‐1, Erk and Akt, but not of Src or STAT3. Furthermore, PF2362376 inhibited proliferation of canine OSA cell lines and induced cell death at biologically achievable concentrations. Last, activities associated with Met signalling including migration, invasion, branching morphogenesis and colony formation in soft agar were blocked by PF2362376. These studies support the notion that Met is a relevant target for therapeutic intervention in OSA.     

Telomerase activity in canine osteosarcoma

Appendicular osteosarcoma (OSA) is the most common primary bone tumour in dogs, and the prognosis with standard of care therapy of amputation and adjunctive chemotherapy is generally poor, with median survival times of 1 year. The ability of neoplastic cells to maintain their telomere length, by either telomerase activity or alternate methods, is an important step in tumour development and malignancy. The purpose of this study was to determine the presence of telomerase activity in canine OSA. To evaluate the frequency of alternative lengthening of telomeres in canine OSA, we have used the telomeric repeat amplification protocol in five canine cell lines and in six samples taken from clinical patients at the time of amputation. Our results reveal the presence of telomerase activity in 100% of canine OSA cell lines and 83% of clinical samples evaluated. This is in contrast to human OSA where 25–40% expression levels of telomerase are reported. Importantly, our results not only suggest that canine OSA may serve as a good model for aggressive telomerase‐positive forms of human OSA but also that antitelomerase therapy strategies for treatment of canine OSA may be more successful than in the treatment of majority of human patients with OSA.     

Characterization, Expression and Function of c‐MET in Canine Spontaneous Cancers

Introduction:  Aberrant expression of the proto‐oncogene c‐Met has been noted in a variety of human cancers. In dogs, inappropriate Met expression has been identified in canine osteosarcoma (OSA) tumor samples. To better define the potential role of Met dysregulation in canine cancer, we cloned canine Met, HGF, and HGF activator and evaluated their expression patterns in a variety of canine tumor cell lines.
Methods:  Canine Met, HGF, and HGF activator were cloned from normal canine liver and canine OSA cell lines using primers based on regions of homology between mouse and human sequences as well as 5' and 3' RACE.
Results:  Inappropriate expression of Met was found in canine cell lines derived from OSAs, mast cell tumors, histiocytic sarcomas, hemangiosarcoma, and melanomas. Both HGF and HGF activator were found to be expressed in several of these tumor cell lines, providing evidence of a possible autocrine loop of Met stimulation. Incubation of canine tumor cell lines with rhHGF resulted in Met autophosphorylation and activation of the downstream signaling elements Gab1, Akt and Erk1/2. Scattering of tumor cells in response to HGF occurred under conditions of cell stress, such as serum starvation. Lastly, the Met inhibitor PHA‐665752 blocked HGF induced phosphorylation of canine Met and Gab1.
Conclusions:  These studies provide evidence that similar to the case in human tumors, aberrant Met expression may play an important role in the biology of canine cancer. As such, inhibition of Met function may represent a potentially useful novel therapeutic approach.     

Analysis of gene expression of prostaglandin EP4 receptor in canine osteosarcoma

In many human cancers, the expression of the prostaglandin receptor EP4 (EP4R) is associated with the development of malignancy and a poor prognosis. The expression of EP4R has not yet been evaluated in canine tumors. The objective of this study was to characterize the messenger RNA (mRNA) expression of EP4R in canine osteosarcoma (OSA). Gene expression of EP4R was evaluated using RNA in-situ hybridization (RNAscope). In all canine OSA samples evaluated, strong universal positive expression of EP4R was identified. Gene expression was significantly higher in OSA tissue samples than in normal nasal turbinate bone, possibly implicating EP4R in the pathogenesis of canine OSA.     

Interleukin‐11 receptor alpha is expressed on canine osteosarcoma

Osteosarcoma (OSA) is the most common bone tumour in humans and companion animals, and has a poor long‐term prognosis. The identification of new markers and targeted therapies may help increase long‐term survival of these patients. Previous studies have demonstrated that interleukin‐11 receptor alpha (IL‐11Rα) is expressed in human and murine OSA but not in normal bone. The current study demonstrated via western analysis, immunoflourescence and immunohistochemistry that IL‐11Rα was expressed in primary canine OSA tissues as well as in a number of canine OSA cell lines, but not in normal canine bone. Cytotoxin‐conjugated antibodies targeting IL‐11Rα‐mediated canine OSA cytotoxicity. Thus, canine OSA may be a valuable model for the evaluation of IL‐11Rα directed therapies.     

Met interacts with EGFR and Ron in canine osteosarcoma

The receptor tyrosine kinase (RTK) Met is known to be over‐expressed in canine osteosarcoma (OSA). In human cancers, the RTKs Met, epidermal growth factor receptor (EGFR) and Ron are frequently co‐expressed and engage in heterodimerization, altering signal transduction and promoting resistance to targeted therapeutics. We found that EGFR and Ron are expressed in canine OSA cell lines and primary tissues, EGFR and Ron are frequently phosphorylated in OSA tumour samples, and Met is co‐associated with EGFR and Ron in canine OSA cell lines. Transforming growth factor alpha (TGFα) and hepatocyte growth factor (HGF) stimulation induced amplification of ERK1/2 and STAT3 phosphorylation in OSA cells and Met was phosphorylated following TGFα stimulation providing evidence for receptor cross‐talk. Lastly, treatment of OSA cells with combined gefitinib and crizotinib inhibited cell proliferation in an additive manner. Together, these data support the notion that Met, EGFR and Ron interact in OSA cells and as such, may represent viable targets for therapeutic intervention.     

Impact of telomerase status on canine osteosarcoma patients

Background: We demonstrated previously that canine osteosarcoma (OSA) cell lines and samples from clinical patients are predominantly telomerase positive. In contrast, the majority of OSA samples from human patients appear to be telomerase negative, maintaining telomere length by an alternative lengthening of telomeres (ALT) mechanism. The purpose of the current study was to examine the telomerase status of a large number of OSA samples from dogs and determine if telomerase status can serve as a prognostic factor. Hypothesis: The majority of clinical canine OSA appendicular lesions will be telomerase positive, and telomerase positivity will negatively impact disease outcome. Animals: Sixty‐seven dogs with appendicular OSA presenting to the Colorado State University Animal Cancer Center for treatment. Methods: The Telomeric Repeat Amplification Protocol was performed on tissue samples from primary canine appendicular OSA to determine the presence of telomerase activity. Telomere restriction fragment (TRF) analysis was utilized to determine telomere length and detect ALT. Outcome data were obtained in a retrospective manner and correlated with telomerase status. Results: Seventy‐three percent of canine OSA samples were telomerase positive. Telomerase status did not have an impact on disease‐free interval or survival time. Nine of 10 telomerase‐negative samples examined were consistent with an ALT phenotype, based on TRF analysis. Conclusions and Clinical Importance: These results are consistent with the hypothesis that the majority of canine OSA are telomerase positive, suggesting that telomerase may be a valuable target for canine OSA therapy. Additionally, telomerase status does not appear to be a prognostic factor in canine OSA.     

Characterization of β-catenin expression in canine osteosarcoma

Osteosarcoma (OSA) is the most frequently occurring malignant primary bone tumour in dogs and children and arises from cells of the osteoblast lineage. Inappropriate Wnt signalling activity has been implicated in human OSA. Altered expression of β-catenin, an integral member of the Wnt signalling pathway, has been associated with numerous human cancers, including OSA. In this study, 30 of the 37 primary canine OSA tissues and 2 of the 3 metastatic OSAs were positive for β-catenin expression as determined by immunohistochemistry, whereas 2 normal bones stained negative for β-catenin. No mutations were identified in exon 3 of β-catenin in the three OSA cases in which DNA sequencing was performed. Finally, there was no relationship between β-catenin expression and overall survival time or disease-free interval. Our results indicate β-catenin is frequently expressed within the cytoplasm of neoplastic cells in canine OSA but contains no detectable mutations in exon 3, similar to human OSA.     

Development of a new canine osteosarcoma cell line

Establishing a canine osteosarcoma (OSA) cell line can be useful to develop in vivo and in vitro models of OSA. The goal of this study was to develop, characterize and authenticate a new canine OSA cell line and a clone. A cell line and a clone were developed with standard cell culture techniques from a naturally occurring OSA in a dog. The clonal cell line induced a tumour after injection in RAG 1‐deficient mouse. Histology was consistent with OSA. The original tumour from the dog and the tumour induced in the mouse were both reactive with vimentin and osteonectin (ON). The parent cell line and clonal cell line were reactive with ON, osteocalcin and alkaline phosphatase. Loss of heterozygosity was found in the same three microsatellite markers in the parent and clonal cell lines, and the tumour tissue grown in the mouse.     

In vitro and in vivo effects of toceranib phosphate on canine osteosarcoma cell lines and xenograft orthotopic models

Canine osteosarcoma (OSA) is the most common primary malignant bone tumour in dogs, and it has a high metastatic rate and poor prognosis. Toceranib phosphate (TOC; Palladia, Zoetis) is a veterinary tyrosine kinase inhibitor that selectively inhibits VEGFR‐2, PDGFRs and c‐Kit, but its efficacy is not yet fully understood in the treatment of canine OSA. Here, we evaluated the functional effects of TOC on six OSA cell lines by transwell, wound healing and colony formation assays. Subsequently, two cell lines (Wall and Penny) were selected and were inoculated in mice by intrafemoral injection to develop an orthotopic xenograft model of canine OSA. For each cell line, 30 mice were xenografted; half of them were used as controls, and the other half were treated with TOC at 40 mg/kg body weight for 20 days. TOC inhibited cell growth of all cell lines, but reduced invasion and migration was only observed in Penny and Wall cell lines. In mice engrafted with Penny cells and subjected to TOC treatment, decreased tumour growth was observed, and PDGFRs and c‐Kit mRNA were downregulated. Immunohistochemical analyses demonstrated a significant reduction of Ki67 staining in treated mice when compared to controls. The results obtained here demonstrate that TOC is able to slightly inhibit cell growth in vitro, while its effect is evident only in a Penny cell xenograft model, in which TOC significantly reduced tumour size and the Ki67 index without modifying apoptosis markers.     

Intrinsic radiosensitivity and repair of sublethal radiation-induced damage in canine osteosarcoma cell lines

OBJECTIVE: To characterize the radiosensitivity and capacity for sublethal damage repair (SLDR) of radiation-induced injury in 4 canine osteosarcoma cell lines. SAMPLE POPULATION: 4 canine osteosarcoma cell lines (HMPOS, POS, COS 31, and D17). PROCEDURES: A clonogenic colony-forming assay was used to evaluate the cell lines' intrinsic radiosensitivities and SLDR capacities. Dose-response curves for the cell lines were generated by fitting the surviving fractions after radiation doses of 0 (control cells), 1, 2, 3, 6, and 9 Gy to a linear quadratic model. To evaluate SLDR, cell lines were exposed to 2 doses of 3 Gy (split-dose experiments) at an interval of 0 (single 6-Gy dose), 2, 4, 6, or 24 hours, after which the surviving fractions were assessed. RESULTS: Mean surviving fraction did not differ significantly among the 4 cell lines at the radiation doses tested. Mean surviving fraction at 2 Gy was high (0.62), and the alpha/beta ratios (predictor of tissue sensitivity to radiation therapy) for the cell lines were low (mean ratio, 3.47). The split-dose experiments revealed a 2.8- to 3.9-fold increase in cell survival when the radiation doses were applied at an interval of 24 hours, compared with cell survival after radiation doses were applied consecutively (0-hour interval). CONCLUSIONS AND CLINICAL RELEVANCE: Results indicated that these canine osteosarcoma cell lines are fairly radioresistant; alpha/beta ratios were similar to those of nonneoplastic, late-responding tissues. Future clinical investigations should involve increasing the fraction size in a manner that maximizes tumor killing without adverse effects on the nonneoplastic surrounding tissues.