Phase II study of the oral selective inhibitor of nuclear export (SINE) KPT-335 (verdinexor) in dogs with lymphoma.

BACKGROUND: Chemotherapeutic options for the treatment of canine lymphoma have not changed in several decades necessitating the identification of new therapeutics to improve patient outcome. KPT-335 (verdinexor) is a novel orally bioavailable selective inhibitor of nuclear export (SINE) that exhibited anti-tumor activity against non-Hodgkin lymphoma in a prior phase I study. The objective of this phase II study was to expand upon the initial findings and assess the activity and safety in a larger population of dogs with lymphoma. RESULTS: Fifty-eight dogs with naïve or progressive B-cell and T-cell lymphoma were enrolled in this clinical trial. KPT-335 was administered orally in one of three dosing groups, based on the previously established biologically active dose of 1.5 mg/kg three times weekly. Treatment with single-agent, orally administered KPT-335 resulted in an objective response rate (ORR) of 37%, of which dogs with T-cell lymphoma had an ORR of 71%. KPT-335 was well tolerated in all dose groups with grade 1-2 anorexia being the most common adverse event. Anorexia was responsive to symptomatic and supportive medications, including prednisone. CONCLUSIONS: These data demonstrate that KPT-335 has biologic activity in canine lymphoma, and support continued evaluation of SINE compounds such as KPT-335 in combination with standard chemotherapeutics in canine lymphoma.

Novel genomic prognostic biomarkers for dogs with cancer.

BACKGROUND: Growing evidence from dogs and humans supports the abundance of mutation-based biomarkers in tumors of dogs. Increasing the use of clinical genomic diagnostic testing now provides another powerful data source for biomarker discovery. HYPOTHESIS: Analyzed clinical outcomes in dogs with cancer profiled using SearchLight DNA, a cancer gene panel for dogs, to identify mutations with prognostic value. ANIMALS: A total of 127 cases of cancer in dogs were analyzed using SearchLight DNA and for which clinical outcome information was available. METHODS: Clinical data points were collected by medical record review. Variables including mutated genes, mutations, signalment, and treatment were fitted using Cox proportional hazard models to identify factors associated with progression-free survival (PFS). The log-rank test was used to compare PFS between patients receiving and not receiving targeted treatment before first progression. RESULTS: Combined genomic and outcomes analysis identified 336 unique mutations in 89 genes across 26 cancer types. Mutations in 6 genes (CCND1, CCND3, SMARCB1, FANCG, CDKN2A/B, and MSH6) were significantly associated with shorter PFS. Dogs that received targeted treatment before first progression (n = 45) experienced significantly longer PFS compared with those that did not (n = 82, P = .01). This significance held true for 29 dogs that received genomically informed targeted treatment compared with those that did not (P = .05). CONCLUSION AND CLINICAL IMPORTANCE: We identified novel mutations with prognostic value and demonstrate the benefit of targeted treatment across multiple cancer types. These results provide clinical evidence of the potential for genomics and precision medicine in dogs with cancer.

Tolerability of oral sorafenib in pet dogs with a diagnosis of cancer.

Sorafenib is a multi-target small molecule inhibitor of the RAF kinase family and VEGFR-2/PDGFR. The US Food and Drug Administration approved sorafenib in human patients with liver, thyroid, or renal carcinoma. The aim of this study was to help guide future pharmacokinetic (PK) studies of sorafenib in dogs with a cancer diagnosis. Client-owned dogs were eligible if they had a cytologic or histologic diagnosis of cancer. Patients were enrolled at escalating doses of sorafenib. Patients were evaluable for the study if they received at least one dose of sorafenib and presented 1 week later for a follow-up examination, blood work, and assessment of drug tolerability. The goal of this study was not to define a maximum tolerated dose as may be reasonable in conventional cytotoxic chemotherapy drugs, but rather to describe the tolerability of this drug in dogs with a cancer diagnosis, as a prequel to future sorafenib PK studies. No patients in the study had any evidence of adverse events that were attributable to sorafenib. Doses of 3 mg/kg were well tolerated and associated with a suggestion of clinical activity, supportive of future PK, and pharmacodynamic analysis. Such future studies are recommended at this dose to define the associated exposure achieved and determine a reasonable schedule for sorafenib administration.

Vascular remodeling marks tumors that recur during chronic suppression of angiogenesis.

The potential for avoiding acquired resistance to therapy has been proposed as one compelling theoretical advantage of antiangiogenic therapy based on the normal genetic status of the target vasculature. However, previous work has demonstrated that tumors may resume growth after initial inhibition if antiangiogenic blockade is continued for an extended period. The mechanisms of this recurrent growth are unclear. In these studies, we characterized molecular changes in vasculature during apparent resumption of xenograft growth after initial inhibition by vascular endothelial growth factor blockade, "metronome" topotecan chemotherapy, and combined agents in a xenograft murine model of human Wilms' tumor. Tumors that grew during antiangiogenic blockade developed as viable clusters surrounding strikingly remodeled vessels. These vessels displayed significant increases in diameter and active proliferation of vascular mural cells and expressed platelet-derived growth factor-B, a factor that functions to enhance vascular integrity via stromal cell recruitment. In addition, remodeled vessels were marked by expression of ephrinB2, required for proper assembly of stromal cells into vasculature. Thus, enhanced vascular stability appears to characterize tumor vessel response to chronic antiangiogenesis, features that potentially support increased perfusion and recurrent tumor growth.

Distinct response of experimental neuroblastoma to combination antiangiogenic strategies.

BACKGROUND: The authors have shown previously that experimental neuroblastoma is partially inhibited (48%) by antivascular endothelial growth factor (anti-VEGF) antibody. The topoisomerase-I inhibitor, topotecan, has been shown to have antiangiogenic activity when administered in a low-dose, high-frequency regimen. We hypothesized that combining topotecan with anti-VEGF would suppress neuroblastoma more effectively than either agent alone. METHODS: A total of 10(6) neuroblastoma cells were implanted intrarenally in athymic mice. Animals received vehicle, topotecan, anti-VEGF, or topotecan plus anti-VEGF (n = 9, 20, 20, 20, respectively). All control and half the treated mice were killed at 6 weeks. Remaining (rebound) mice were maintained without treatment for 3 more weeks. Patterns of vasculature and apoptosis were determined immunohistochemically. RESULTS: Tumor weights at 6 weeks were reduced significantly in topotecan-only (0.07g) and combination-treated animals (0.08 g), compared with controls or anti-VEGF--treated mice (1.18 g, 0.53 g; P <.0007, all). At 9 weeks, rebound tumor weights were greatest in anti-VEGF (2.82 g), intermediate in topotecan (1.82 g), and least in combination-treated animals (1.47 g); however, the only significant difference was between anti-VEGF and combination therapy (P = 0.04). All treated tumors were vascularized sparsely in comparison with controls at 6 weeks, but exhibited brisk neoangiogenesis at 9 weeks. CONCLUSIONS: Topotecan either with or without anti-VEGF antibody significantly suppresses neuroblastoma xenograft growth in comparison with controls or anti-VEGF antibody alone. Combining topotecan with anti-VEGF antibody significantly inhibited rebound tumor growth in comparison with anti-VEGF antibody alone. Combination therapy may improve durability of antiangiogenic inhibition of neuroblastoma.

p53 accumulation in favorable-histology Wilms tumor is associated with angiogenesis and clinically aggressive disease.

BACKGROUND/PURPOSE: Unfavorable histology (UH) in Wilms tumor has been linked to malfunction of the p53 tumor suppressor gene, which regulates (1) the endogenous angiogenesis suppressor thrombospondin-1 (TSP-1) and (2) vascular endothelial growth factor (VEGF). The authors hypothesized that clinically aggressive favorable histology Wilms tumor (FH), like UH, but distinct from standard-risk FH disease, would display altered p53/TSP-1 function and upregulated angiogenesis. METHODS: Three Wilms tumor specimens manifesting different histology and clinical behavior were obtained: clinically aggressive UH, clinically aggressive FH, and standard-risk FH disease. Xenografts were induced intrarenally in athymic mice. P53, TSP-1, and VEGF status and neovascularity were assessed in tumor tissues. Lungs were evaluated for metastasis. RESULTS: Clinically aggressive FH Wilms tumor displayed progressive alteration in p53/TSP-1 status and upregulation of VEGF. Such alteration was observed in the UH tumor, but was absent from the standard-risk FH tumor. Xenografts from clinically aggressive tumors displayed brisk neoangiogenesis and yielded lung metastases. CONCLUSIONS: This is the first report of altered p53/TSP-1 function in association with clinically aggressive behavior in FH Wilms tumor. These characteristics were not observed in parallel studies of a nonaggressive FH tumor. Loss of wild-type p53 function may contribute to disease progression in FH Wilms tumor, in part by upregulation of VEGF.

Resistance of a VEGF-producing tumor to anti-VEGF antibody: unimpeded growth of human rhabdoid tumor xenografts.

BACKGROUND/PURPOSE: Rhabdoid tumor of the kidney (RTK) is a lethal malignancy of childhood for which there currently are no effective therapies. Because vascular endothelial growth factor (VEGF) is nearly ubiquitous in human tumors, the authors hypothesized that a xenograft model of RTK would (1) express VEGF and (2) respond to anti-VEGF intervention. METHODS: A total of 2 x 10(6) cultured RTK cells were implanted intrarenally (G-401) in athymic mice. Control/treated animals received either vehicle (phosphate-buffered saline, PBS) or anti-VEGF antibody (anti-VEGF) for 5 weeks (n = 20, 17, respectively). Vasculature was mapped by angiography and immunostaining. Apoptosis was assessed by TdT-mediated dUTP nick end labeling (TUNEL) assay, VEGF expression examined by reverse transcription polymerase chain reaction, and tumor weights compared by Kruskal-Wallis analysis. RESULTS: Mean tumor weights were not altered significantly by anti-VEGF (0.78-g, controls v 0.56-g treated tumors; P value, not significant). Grossly, xenografts grew in a novel manner, encasing rather than invading the kidney, and did not metastasize. PECAM-1 immunostaining and fluorescein angiography showed similar vascularity in control and treated xenografts. Both apoptosis and VEGF expression were unchanged in treated specimens. CONCLUSIONS: Unexpectedly, growth of RTK xenografts was not inhibited by specific anti-VEGF antibody, although these tumors express significant amounts of VEGF. In addition, RTK vasculature, apoptosis, and VEGF expression were not substantially altered by anti-VEGF antibody. These results suggest that tumor-derived VEGF is of highly variable importance in different malignancies.

Topotecan is anti-angiogenic in experimental hepatoblastoma.

BACKGROUND: Advanced hepatoblastoma often is lethal despite current therapies, yet development of novel approaches has been hampered by the lack of biologically relevant models. One new strategy selectively targets endothelium rather than tumor cells using frequently administered, low-dose ("metronome") chemotherapy. Metronome topotecan has antiangiogenic activity in some experimental tumors. The authors developed a xenograft model of human hepatoblastoma to test the effect of metronome topotecan in this system. METHODS: Xenografts resulted from intrarenal injection of cultured human hepatoblastoma cells in athymic mice. Topotecan (0.36 mg/kg/dose) or vehicle was injected intraperitoneally 5 times per week. At week 6, 10 control/treated mice were killed, and remaining animals were maintained without treatment until week 8. Tumor weights were compared by Kruskal-Wallis analysis, and vascular alterations were ascertained by specific immunostaining. RESULTS: Metronome topotecan affected tumor weights in a delayed fashion: weights were diminished significantly only at 8 weeks (treated v control: 6 weeks, 0.59 g v 82 g, P value, not significant; 8 weeks, 1.13 g v 3.82; P <.02). Decreased vascularity and increased endothelial cell apoptosis were observed in treated xenografts. CONCLUSIONS: Metronome topotecan inhibits growth and neovascularization in experimental hepatoblastoma. The durability of this effect is novel and has not been observed in other xenograft tumor models. Cytotoxic targeting of endothelial cells may hold particular promise for therapy of children with advanced hepatoblastoma. .

Potent VEGF blockade causes regression of coopted vessels in a model of neuroblastoma.

Vascular endothelial growth factor (VEGF) plays a key role in human tumor angiogenesis. We compared the effects of inhibitors of VEGF with different specificities in a xenograft model of neuroblastoma. Cultured human neuroblastoma NGP-GFP cells were implanted intrarenally in nude mice. Three anti-VEGF agents were tested: an anti-human VEGF(165) RNA-based fluoropyrimidine aptamer; a monoclonal anti-human VEGF antibody; and VEGF-Trap, a composite decoy receptor based on VEGFR-1 and VEGFR-2 fused to an Fc segment of IgG1. A wide range of efficacy was observed, with high-dose VEGF-Trap causing the greatest inhibition of tumor growth (81% compared with controls). We examined tumor angiogenesis and found that early in tumor formation, cooption of host vasculature occurs. We postulate that this coopted vasculature serves as a source of blood supply during the initial phase of tumor growth. Subsequently, control tumors undergo vigorous growth and remodeling of vascular networks, which results in disappearance of the coopted vessels. However, if VEGF function is blocked, cooption of host vessels may persist. Persistent cooption, therefore, may represent a novel mechanism by which neuroblastoma can partly evade antiangiogenic therapy and may explain why experimental neuroblastoma is less susceptible to VEGF blockade than a parallel model of Wilms tumor. However, more effective VEGF blockade, as achieved by high doses of VEGF-Trap, can lead to regression of coopted vascular structures. These results demonstrate that cooption of host vasculature is an early event in tumor formation, and that persistence of this effect is related to the degree of blockade of VEGF activity.