Inhibition of telomerase in canine cancer cells following telomestatin treatment

Telomere shortening in normal somatic cells has been proposed as a major barrier to unlimited cellular proliferation. Telomerase is an enzyme capable of maintaining telomere length, and thus bypassing this barrier. In human beings, telomerase activity is restricted to cancer cells and cells of stem or germ cell lineages. Dogs represent a potentially useful clinical model for the development of telomerase‐based therapies because telomerase activity is also restricted to cancer cells and stem cells in this species. We examined the ability of telomestatin to inhibit telomerase activity in telomerase‐positive D17 and CMT7 canine cancer cell lines. At a concentration of 2 μM, telomestatin treatment resulted in a decrease in telomerase activity, telomere shortening, growth inhibition and apoptosis in telomerase‐positive cancer cells. These effects were not seen in telomerase‐negative skin fibroblasts or negative controls. These results confirm that telomestatin specifically inhibits telomerase activity in canine cancer cells and strengthens the usefulness of dogs as a model for testing telomerase‐based therapies.     

The human and canine TERT promoters function equivalently in human and canine cells

Telomerase targeted cancer gene therapy is being exploited for treatment of human cancer. The high incidence and many comparative aspects of human and canine cancer and the compliance and dedication of dog owners to treat cancer makes the canine pet population a good clinical model for investigating and developing new cancer therapeutics. Here, we report that the human telomerase promoter operates in canine cells, suggesting that human telomerase promoter-driven cancer therapy can be used to treat cancer in canines. Therefore, the canine pet population can act as a clinical model for new drug development based on telomerase therapeutics.     

Evaluation of telomerase-targeted therapies in canine cancer cell lines

Despite advances in conventional therapeutics, cancer remains an invariably fatal disease, the major challenge being to develop tumour‐specific cancer treatment strategies. Current treatments such as chemotherapy and radiotherapy rely on a crude distinction between cancer cells and normal cells. However, with an increased understanding of the molecular events in the development of cancer, it is possible that far more innovative and targeted approaches can be developed. From studies on humans and dogs, the enzyme telomerase has emerged as a central unifying mechanism underlying the immortal phenotype of cancer and has thus become a candidate for differentiating between normal and cancer cells. The level and frequency of telomerase activity and component gene expression in cancers reinforces this as a potential target for cancer therapies. This article describes two approaches to target cancer by capitalizing on the expression of this enzyme. In the first approach, we target the enzyme itself, the goal being to cause cancer cell death. In the second approach, we utilize the respective gene promoters for telomerase component enzymes to drive expression of a reporter gene in cancer cell lines. The results demonstrated that targeted gene expression using promoter elements can be achieved specifically in telomerase‐positive cell lines. However, targeting the enzyme itself proved less successful and warrants investigations into alternative approaches.     

Telomerase: a potential diagnostic and therapeutic tool in canine oncology

In recent years there has been considerable interest in telomerase as a target for therapeutic intervention in oncology. This largely stems from the vast number of studies that have demonstrated expression and activity of the enzyme telomerase in the majority of human cancer tissues with little or no activity detectable in normal somatic tissues. These studies have led to an interest in the role of telomerase in cancers associated with domesticated species, in particular tumors that affect dogs. This article reviews the biology of telomerase and the biological significance of telomerase activity in canine tumors and discusses the clinical implications of telomerase expression in canine cancers with regard to therapeutics and diagnostics.     

Telomeres and telomerase: Biological and clinical importance in dogs

In recent years in human oncology the enzyme telomerase has emerged as an ideal target for cancer therapy. This has led to the assessment of telomerase in cancers in companion animals, mainly dogs and these studies confirm that in dogs, like humans, telomere maintenance by telomerase is the primary mechanism by which cancer cells overcome their mortality and extend their lifespan. This review aims to provide an introduction to the biology of telomeres and telomerase and to discuss some of the telomere/telomerase directed therapeutic methodologies currently under development which may be of benefit to the canine cancer patient.     

Comparative analysis of MAPK and PI3K/AKT pathway activation and inhibition in human and canine melanoma

The lack of advanced animal models of human cancers is considered a barrier to developing effective therapeutics. Canine and human melanomas are histologically disparate but show similar disease progression and response to therapies. The purpose of these studies was to compare human and canine melanoma tumours and cell lines regarding MAPK and PI3K/AKT signalling dysregulation, and response to select molecularly targeted agents. Pathway activation was investigated via microarray and mutational analysis. Growth inhibition and cell cycle effects were assessed for pathway inhibitors AZD6244 (MAPK) and rapamycin (PI3K/AKT) in human and canine melanoma cells. Human and canine melanoma share similar differential gene expression patterns within the MAPK and PI3K/AKT pathways. Constitutive pathway activation and similar sensitivity to AZD6244 and rapamycin was observed in human and canine cells. These results show that human and canine melanoma share activation and sensitivity to inhibition of cancer‐related signalling pathways despite differences in activating mutations.     

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.     

Wnt5a expression in canine osteosarcoma

Osteosarcoma is the most common primary malignancy of bone in dogs and is associated with poor long‐term outcomes due to its highly metastatic nature. A better understanding of the signalling pathways and proteins involved with osteosarcoma pathogenesis may aid in improved outcomes through the use of targeted therapies. The Wnt5a protein, a ligand for the non‐canonical Wnt signalling pathway, is implicated in mediating the aggressiveness of cancer cell lines, including those of human osteosarcoma origin. Given the close relationship between human and canine osteosarcoma, the primary goal of this study was to characterize Wnt5a expression in canine osteosarcoma. Second, if Wnt5a expression was present in canine osteosarcoma, the study aimed to determine any potential association with clinical outcome and clinical variables in similarly treated osteosarcoma‐bearing dogs. Wnt5a expression was present in 26 of the 48 (54%) cases of canine osteosarcoma. Wnt5a expression was not associated with progression‐free survival (P = 0.4) or overall survival (P = 0.1).     

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.     

Oncolytic gene therapy for canine cancers: teaching old dog viruses new tricks

The use of viruses to treat cancer has been studied for decades. With the advancement of molecular biology, viruses have been modified and genetically engineered to optimize their ability to target cancer cells. Canine viruses, such as distemper virus and adenovirus, are being exploited for the treatment of canine cancer as the dog has proven to be a good comparative model for human cancer research and proof of concept investigations. In this review, we introduce the concept of oncolytic viruses and describe some of the preliminary attempts to use oncolytic viruses for the treatment of canine cancer.     

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.     

Molecular biological aspects on canine and human mammary tumors

The high incidence of mammary tumor disease reported in certain canine breeds suggests a significant genetic component, as has already been described in human familial breast cancer-in BRCA1- and BRCA2-associated breast cancer in particular. The identification of genetic risk factors is critical to improvements in the prevention, diagnosis, and treatment of these tumors. In recent years, there has been significant progress in developing the tools and reagents necessary to analyze the canine genome. This work has culminated in a high-quality draft genome sequence, as well as a single-nucleotide polymorphism map and single-nucleotide polymorphism arrays for genomewide association analysis. These tools provide an unprecedented opportunity to characterize the genetic influences in canine diseases such as cancer, eventually allowing for exploration of more effective therapies. Given the high homology between the canine genome sequence and its human counterpart--as well as the many similarities regarding the morphology, biological behavior, and clinical course of mammary tumors in both species--the dog has proven to be an excellent comparative model. This review highlights the comparative aspects regarding certain areas within molecular biology, and it discusses future perspectives. The findings in larger genomewide association analyses and cDNA expression arrays are described, and the BRCA1/BRCA2 complex is compared in detail between the 2 species.     

Potential markers for detection of circulating canine mammary tumor cells in the peripheral blood

Major discrepancies exist between histological predictions and actual metastatic potential of canine mammary tumors. Detection of circulating tumor cells (CTC) has a proven prognostic value for human breast cancer but similar markers for canine CTC are lacking. In the present study a panel of 16 human CTC markers was tested for their ability to specifically and sensitively detect canine carcinoma cells in peripheral blood. PCR assays for CK19, ERBB2, EGFR, CLDN7 and ELF3 were able to sensitively detect one carcinoma cell in up to 10(7) peripheral blood leukocytes. These CTC markers are thus candidate markers for identifying canine mammary CTC in the peripheral blood and may serve as prognostic factors for metastatic behavior in the future.     

The oncolytic effects of reovirus in canine solid tumor cell lines

Oncolytic virotherapy is a new strategy for cancer treatment for humans and dogs. Reovirus has been proven to be a potent oncolytic virus in human medicine. Our laboratory has previously reported that canine mast cell tumor and canine lymphoma were susceptible to reovirus. In this study, canine solid tumor cell lines (mammary gland tumor, osteosarcoma and malignant melanoma) were tested to determine their susceptibility towards reovirus. We demonstrated that reovirus induces more than 50% cell death in three canine mammary gland tumors and one canine malignant melanoma cell line. The reovirus-induced cell death occurred via the activation of caspase 3. Ras activation has been shown to be one of the important mechanisms of reovirus-susceptibility in human cancers. However, Ras activation was not related to the reovirus-susceptibility in canine solid tumor cell lines, which was similar to reports in canine mast cell tumor and canine lymphoma. The results of this study highly suggest that canine mammary gland tumor and canine malignant melanoma are also potential candidates for reovirus therapy in veterinary oncology.