Igor Moskalev

Targeting HER2 with T-DM1, an Antibody Cytotoxic Drug Conjugate, is Effective in HER2 Over Expressing Bladder Cancer

PURPOSE Systemic therapy for advanced bladder cancer has not changed substantially in more than 2 decades and mortality rates remain high. The recognition of HER2 over expression in bladder cancer has made HER2 a promising therapeutic target. T-DM1, a new drug consisting of the HER2 antibody trastuzumab conjugated with a cytotoxic agent, has been shown in breast cancer to be superior to trastuzumab. We tested T-DM1 in preclinical models of bladder cancer. MATERIALS AND METHODS We evaluated the effect of T-DM1 compared to trastuzumab in different in vitro and in vivo models of HER2 over expressing bladder cancer. RESULTS RT4V6 was the highest HER2 expressing bladder cancer cell line and it showed higher growth inhibition with T-DM1 compared to trastuzumab. T-DM1 but not trastuzumab induced apoptosis of RT4V6 cells after G2/M arrest on cell cycle analysis. HER2 expression was higher in cell lines with acquired cisplatin resistance compared to the corresponding parental cell lines. Resistant cells showed higher sensitivity to T-DM1 by the induction of apoptosis. In addition, cells cultured in anchorage independent conditions increased HER2 expression compared to cells cultured in adherent conditions and T-DM1 significantly inhibited colony formation in soft agar compared to trastuzumab. In an orthotopic bladder cancer xenograft model tumor growth of cisplatin resistant RT112 was significantly inhibited by T-DM1 via the induction of apoptosis compared to treatment with control IgG or trastuzumab. CONCLUSIONS T-DM1 has promising antitumor effects in preclinical models of HER2 over expressing bladder cancer.

Ultrasound-guided intramural inoculation of orthotopic bladder cancer xenografts: a novel high-precision approach.

Orthotopic bladder cancer xenografts are essential for testing novel therapies and molecular manipulations of cell lines in vivo. Current xenografts rely on tumor cell inoculation by intravesical instillation or direct injection into the bladder wall. Instillation is limited by the lack of cell lines that are tumorigenic when delivered in this manner. The invasive model inflicts morbidity on the mice by the need for laparotomy and mobilization of the bladder. Furthermore this procedure is complex and time-consuming. Three bladder cancer cell lines (UM-UC1, UM-UC3, UM-UC13) were inoculated into 50 athymic nude mice by percutaneous injection under ultrasound guidance. PBS was first injected between the muscle wall and the mucosa to separate these layers, and tumor cells were subsequently injected into this space. Bioluminescence and ultrasound were used to monitor tumor growth. Contrast-enhanced ultrasound was used to study changes in tumor perfusion after systemic gemcitabine/cisplatin treatment. To demonstrate proof of principle that therapeutic agents can be injected into established xenografts under ultrasound guidance, oncolytic virus (VSV) was injected into UM-UC3 tumors. Xenograft tissue was harvested for immunohistochemistry after 23–37 days. Percutaneous injection of tumor cells into the bladder wall was performed efficiently (mean time: 5.7 min) and without complications in all 50 animals. Ultrasound and bioluminescence confirmed presence of tumor in the anterior bladder wall in all animals 3 days later. The average tumor volumes increased steadily over the study period. UM-UC13 tumors showed a marked decrease in volume and perfusion after chemotherapy. Immunohistochemical staining for VSV-G demonstrated virus uptake in all UM-UC3 tumors after intratumoral injection. We have developed a novel method for creating orthotopic bladder cancer xenograft in a minimally invasive fashion. In our hands this has replaced the traditional model requiring laparotomy, because this model is more time efficient, more precise and associated with less morbidity for the mice.

Local checkpoint inhibition of CTLA-4 as a monotherapy or in combination with anti-PD1 prevents the growth of murine bladder cancer

Checkpoint blockade of CTLA‐4 results in long‐lasting survival benefits in metastatic cancer patients. However, patients treated with CTLA‐4 blockade have suffered from immune‐related adverse events, most likely due to the breadth of the induced T‐cell activation. Here, we investigated the efficacy of a local low‐dose anti‐CTLA‐4 administration for treatment of subcutaneous or orthotopic murine bladder 49 (MB49) bladder carcinoma in C57BL/6 mice. When MB49 tumors were grown s.c., peritumoral (p.t.) injection of anti‐CTLA‐4 treatment was equally effective as intravenous or s.c. (nontumor bearing flank) administration. Notably, p.t. injection was associated with lower circulating antibody levels and decreased IL‐6 serum levels as compared to systemic treatment. Ultrasound‐guided intratumoral anti‐CTLA‐4 antibody treatment of orthotopically growing MB49 tumors resulted in tumor regression, with more than tenfold reduction in systemic antibody levels as compared to i.v. or s.c. administration, in line with the compartmentally restrained nature of the bladder. Local anti‐CTLA‐4 therapy in combination with anti‐PD‐1 therapy resulted in complete responses, superior to each therapy alone. In addition, p.t. anti‐CTLA‐4 therapy was potentiated by depletion of regulatory T cells. Our results demonstrate that local anti‐CTLA‐4 antibody therapy is equally effective as systemic administration, but reduces systemic antibody levels and cytokine release, and enhances the response to anti‐PD1 therapy.

Suppression of progranulin expression inhibits bladder cancer growth and sensitizes cancer cells to cisplatin

We have recently demonstrated a critical role for progranulin in bladder cancer. Progranulin contributes, as an autocrine growth factor, to the transformed phenotype by modulating Akt-and MAPK-driven motility, invasion and anchorage-independent growth. Progranulin also induces F-actin remodeling by interacting with the F-actin binding protein drebrin. In addition, progranulin is overexpressed in invasive bladder cancer compared to normal tissue controls, suggesting that progranulin might play a key role in driving the transition to the invasive phenotype of urothelial cancer. However, it is not established whether targeting progranulin could have therapeutic effects on bladder cancer. In this study, we stably depleted urothelial cancer cells of endogenous progranulin by shRNA approaches and determined that progranulin depletion severely inhibited the ability of tumorigenic urothelial cancer cells to migrate, invade and grow in anchorage-independency. We further demonstrate that progranulin expression is critical for tumor growth in vivo, in both xenograft and orthotopic tumor models. Notably, progranulin levels correlated with response to cisplatin treatment and were upregulated in bladder tumors. Our data indicate that progranulin may constitute a novel target for therapeutic intervention in bladder tumors. In addition, progranulin may serve as a novel biomarker for bladder cancer.

Orthotopic Mouse Models of Urothelial Cancer

Orthotopic mouse models of urothelial cancer are essential for testing novel therapies and molecular manipulations of cell lines in vivo. These models are either established by orthotopic inoculation of human (xenograft models) or murine tumor cells (syngeneic models) in immunocompromised or immune competent mice. Current techniques rely on inoculation by intravesical instillation or direct injection into the bladder wall. Alternative models include the induction of murine bladder tumors by chemical carcinogens (BBN) or genetic engineering (GEM).

Erythropoietin Accelerates the Regeneration of Ureteral Function in a Murine Model of Obstructive Uropathy

PURPOSE Unilateral ureteral obstruction halts ureteral peristalsis, and may cause pain and lead to infection. Ureteral ability to recover after obstruction removal remains unclear. Erythropoietin has protective effects in nonhematopoietic organs and restores peristalsis in hypocontractile intestinal smooth muscle cells. We investigated the role of erythropoietin in ureteral smooth muscle function and its therapeutic value for unilateral ureteral obstruction. MATERIALS AND METHODS Unilateral ureteral obstruction was created for 24, 48 and 72 hours in 22 mice per group using a nontraumatic microclip via laparotomy. We determined erythropoietin, erythropoietin receptor and β-common receptor expression in obstructed and unobstructed ureters by reverse transcriptase-polymerase chain reaction and immunohistochemistry. Ten mice per group received 20 IU erythropoietin for 4 days and controls received saline. Hydronephrosis regression after obstruction removal was assessed by ultrasound. Peristalsis was determined microscopically before and after obstruction removal. RESULTS Erythropoietin, erythropoietin receptor and β-common receptor were expressed in the unobstructed and obstructed ureters of untreated mice. Erythropoietin mRNA was up-regulated in response to obstruction and erythropoietin expression was identified in ureteral smooth muscle. After obstruction removal hydronephrosis and ureteral dysfunction correlated with obstruction duration. Hydronephrosis resolution and ureteral peristalsis restoration were significantly accelerated in erythropoietin treated mice compared to controls. CONCLUSIONS Erythropoietin treatment significantly promoted functional recovery of the ureter after obstruction removal. Erythropoietin may be a helpful strategy for ureteral motility recovery and hydronephrosis resolution in ureteral obstruction.

Minimally invasive establishment of murine orthotopic bladder xenografts.

Orthotopic bladder cancer xenografts are the gold standard to study molecular cellular manipulations and new therapeutic agents in vivo. Suitable cell lines are inoculated either by intravesical instillation (model of nonmuscle invasive growth) or intramural injection into the bladder wall (model of invasive growth). Both procedures are complex and highly time-consuming. Additionally, the superficial model has its shortcomings due to the lack of cell lines that are tumorigenic following instillation. Intramural injection, on the other hand, is marred by the invasiveness of the procedure and the associated morbidity for the host mouse. With these shortcomings in mind, we modified previous methods to develop a minimally invasive approach for creating orthotopic bladder cancer xenografts. Using ultrasound guidance we have successfully performed percutaneous inoculation of the bladder cancer cell lines UM-UC1, UM-UC3 and UM-UC13 into 50 athymic nude. We have been able to demonstrate that this approach is time efficient, precise and safe. With this technique, initially a space is created under the bladder mucosa with PBS, and tumor cells are then injected into this space in a second step. Tumor growth is monitored at regular intervals with bioluminescence imaging and ultrasound. The average tumor volumes increased steadily in in all but one of our 50 mice over the study period. In our institution, this novel approach, which allows bladder cancer xenograft inoculation in a minimally-invasive, rapid and highly precise way, has replaced the traditional model.

Calcium-sensing receptor (CaSR) promotes development of bone metastasis in renal cell carcinoma

Bone metastasis is an important prognostic factor in renal cell carcinoma (RCC). The calcium-sensing receptor (CaSR) has been associated with bone metastasis in several different malignancies. We analyzed the impact of CaSR in bone metastasis in RCC in vitro and in vivo. The RCC cell line 786-O was stably transfected with the CaSR gene and treated with calcium alone or in combination with the CaSR antagonist NPS2143. Afterwards migration, adhesion, proliferation and prominent signaling molecules were analyzed. Calcium treated CaSR-transfected 768-O cells showed an increased adhesion to endothelial cells and the extracellular matrix components fibronectin and collagen I, but not to collagen IV. The chemotactic cell migration and proliferation was also induced by calcium. The activity of SHC, AKT, ERK, P90RSK and JNK were enhanced after calcium treatment of CaSR-transfected cells. These effects were abolished by NPS2143. Development of bone metastasis was evaluated in vivo in a mouse model. Intracardiac injection of CaSR-transfected 768-O cells showed an increased rate of bone metastasis. The results indicate CaSR as an important component in the mechanism of bone metastasis in RCC. Therefore, targeting CaSR might be beneficial in patients with bone metastatic RCC with a high CaSR expression.

Magnetically-actuated drug delivery device (MADDD) for minimally invasive treatment of prostate cancer: An in vivo animal pilot study

The vast majority of prostate cancer presents clinically localized to the prostate without evidence of metastasis. Currently, there are several modalities available to treat this particular disease. Despite radical prostatectomy demonstrating a modest prostate cancer specific mortality benefit in the PIVOT trial, several novel modalities have emerged to treat localized prostate cancer in patients that are either not eligible for surgery or that prefer an alternative approach.

The role of netrin-1 in metastatic renal cell carcinoma treated with sunitinib

Introduction Clear-cell renal cell carcinoma (ccRCC) is the sixth most common malignancy in men in North America. Since ccRCC is a malignancy dependent on neovascularization, current first line systemic therapies like sunitinib, target the formation of new vessels allowing nutrient deprivation and cell death. However, recent studies have shown that patients develop resistance after approximately 1 year of treatment and show disease progression while on therapy. Therefore, we propose to identify the protein(s) responsible for increased migration with the aim of developing a new therapy that will target the identified protein and potentially slow down the progression of the disease. Material and Methods Human renal cancer cell lines (Caki-1, Caki-2, ACHN) were treated with increasing doses of sunitinib to develop a sunitinib-conditioned renal cell carcinoma cell line. mRNA microarray and qPCR were performed to compare the differences in gene expression between Caki-1 sunitinib-conditioned and non-conditioned cells. NTN1 was assessed in our in vivo sunitinib-conditioned mouse model using immunostaining. xCELLigence and scratch assays were used to evaluate migration and MTS was used to evaluate cell viability. Results Human renal cell carcinoma sunitinib-conditioned cell lines showed upregulation of netrin-1 in microarray and q-PCR. Increased migration was demonstrated in Caki-1 sunitinib-conditioned cells when compared to the non-treated ones as well as, increased endothelial cell migration. Silencing of netrin-1 in sunitinib-conditioned Caki-1 cells did not demonstrate a significant reduction in cell migration. Conclusion Netrin-1 is highly upregulated in renal cell carcinoma treated with sunitinib, but has no influence on cell viability or cell migration in metastatic RCC.