Su Jin Jang

Establishment of animal model for the analysis of cancer cell metastasis during radiotherapy

BackgroundΓ-Ionizing radiation (IR) therapy is one of major therapeutic tools in cancer treatment. Nevertheless, γ-IR therapy failed due to occurrence of metastasis, which constitutes a significant obstacle in cancer treatment. The main aim of this investigation was to construct animal model which present metastasis during radiotherapy in a mouse system in vivo and establishes the molecular mechanisms involved.Materials and methodsThe C6L transfectant cell line expressing firefly luciferase (fLuc) was treated with γ-IR, followed by immunoblotting, zymography and invasion assay in vitro. We additionally employed the C6L transfectant cell line to construct xenografts in nude mice, which were irradiated with γ-IR. Irradiated xenograft-containing mice were analyzed via survival curves, measurement of tumor size, and bioluminescence imaging in vivo and ex vivo. Metastatic lesions in organs of mice were further assessed using RT-PCR, H & E staining and immunohistochemistry.Resultsγ-IR treatment of C6L cells induced epithelial-mesenchymal transition (EMT) and increased cell invasion. In irradiated xenograft-containing mice, tumor sizes were decreased dramatically and survival rates extended. Almost all non-irradiated xenograft-containing control mice had died within 4 weeks. However, we also observed luminescence signals in about 22.5% of γ-IR-treated mice. Intestines or lungs of mice displaying luminescence signals contained several lesions, which expressed the fLuc gene and presented histological features of cancer tissues as well as expression of EMT markers.ConclusionsThese findings collectively indicate that occurrences of metastases during γ-IR treatment accompanied induction of EMT markers, including increased MMP activity. Establishment of a murine metastasis model during γ-IR treatment should aid in drug development against cancer metastasis and increase our understanding of the mechanisms underlying the metastatic process.

Detection of Increased 64Cu Uptake by Human Copper Transporter 1 Gene Overexpression Using PET with 64CuCl2 in Human Breast Cancer Xenograft Model

Copper is an essential cofactor for a variety of biochemical processes including oxidative phosphorylation, cellular antioxidant activity, and elimination of free radicals. The copper transporter 1 is known to be involved in cellular uptake of copper ions. In this study, we evaluated the utility of human copper transporter 1 (hCTR1) gene as a new reporter gene for 64Cu PET imaging. Methods: Human breast cancer cells (MDA-MB-231) were infected with a lentiviral vector constitutively expressing the hCTR1 gene under super cytomegalovirus promoter, and positive clones (MDA-MB-231-hCTR1) were selected. The expression of hCTR1 gene in MDA-MB-231-hCTR1 cells was measured by reverse transcription polymerase chain reaction, Western blot, and 64Cu uptake assay. To evaluate the cytotoxic effects induced by hCTR1 expression, the dose-dependent cell survival rate after treatment with cisplatin (Cis-diaminedichloroplatinum (II) [CDDP]) was determined by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay and trypan blue dye exclusion. Small-animal PET images were acquired in tumor-bearing mice from 2 to 48 h after an intravenous injection of 64Cu. Results: The hCTR1 gene expression in MDA-MB-231-hCTR1 cells was confirmed at the RNA and protein expression and the cellular 64Cu uptake level. MTT assay and trypan blue dye exclusion showed that the cell viability of MDA-MB-231-hCTR1 cells decreased more rapidly than that of MDA-MB-231 cells after treatment with CDDP for 96 or 72 h, respectively. Small-animal PET imaging revealed a higher accumulation of 64Cu in MDA-MB-231-hCTR1 tumors than in MDA-MB-231 tumors. With respect to the biodistribution data, the percentage injected dose per gram of 64Cu in the MDA-MB-231 tumors and MDA-MB-231-hCTR1 tumors at 48 h after 64Cu injection was 2.581 ± 0.254 and 5.373 ± 1.098, respectively. Conclusion: An increase in 64Cu uptake induced by the expression of hCTR1 gene was demonstrated in vivo and in vitro, suggesting the potential use of hCTR1 gene as a new imaging reporter gene for PET with 64CuCl2.

Application of bioluminescence imaging to therapeutic intervention of herpes simplex virus type I – Thymidine kinase/ganciclovir in glioma

Lentiviral vector containing the HSV1-tk and firefly luciferase (fLuc) gene was infected into C6 and C6-TL expressing HSV1-tk and fLuc gene was generated. C6-TL showed higher [(125)I]IVDU uptake than C6. The survival rate of C6-TL decreased more rapidly with increasing GCV dose and was well correlated with fLuc activity. The images of microPET clearly demonstrated higher uptake of [(18)F]FHBG into the C6-TL tumor. Inhibition of tumor growth was observed in C6-TL tumor-bearing mice treated with GCV through tumor size measurement and bioluminescence imaging. The therapeutic effect of HSV1-tk/GCV system can be monitored using bioluminescent imaging and tumor size measurement.

Synthesis and Evaluation of a 18F-Labeled 4-Ipomeanol as an Imaging Agent for CYP4B1 Gene Prodrug Activation Therapy

We report the development of a (18)F-labeled 4-ipomeanol (4-IM), which is metabolized by the CYP4B1 enzyme, to image tumors and monitor enzyme-activating anticancer prodrugs. The fluorine-substituted derivative, 1-(3-furyl)-4-hydroxy-5-fluoro-1-pentanone (F-4-IM, 1), was synthesized from 3-furaldehyde. [(18)F]F-4-IM ([(18)F]1) was prepared in 20%-35% radiochemical yield by a fluorine-18 displacement reaction, followed by reduction and deprotection of the ketal group, and was shown to be stable (>96% at 2 hours) in human serum at 37°C. The biodistribution of [(18)F]F-4-IM in normal rats was high in the lung, where CYP4B1 gene is preferentially expressed. We transduced C6-glioma cells with a retrovirus-expressing CYP4B1 (C6-CYP4B1). Evaluation of CYP4B1 expression was confirmed by reverse transcription polymerase chain reaction and MTT assay. Cell assays were carried out using C6 and C6-CYP4B, and the uptake of [(18)F]F-4-IM in these cells was compared with that in parental controls. The uptake ratio of [(18)F]F-4-IM was 2.8-fold higher in C6-CYP4B1 compared with that in parental cells at 1 hour, whereas [(3)H]4-IM was taken up at similar rates in both cell lines after 6 hours. These results suggest that [(18)F]F-4-IM could be a promising PET imaging agent with potential to be used for imaging of CYP4B1-transfected tumor cells, as well as for monitoring CYP4B1 enzyme/prodrug interactions.

131I-labeled chitosan hydrogels for radioembolization: A preclinical study in small animals

INTRODUCTION The purpose of the study was to examine potential of 131I-labeled chitosan hydrogels (Chi) for treatment of liver cancer. METHODS Orthotopic hepatoma was induced by McA-RH7777-fLuc cells (1×107) that were injected into the left hepatic lobe of rats. Ten days later, tumor-bearing rats evidenced by bioluminescence received 125I-labeled Chi with left hepatic artery access. Pharmacokinetics and excretion (n=8) and biodistribution (n=6/time point) were studied after injection. To examine therapeutic potential, animals (n=8/group) were also treated with Chi labeled with or without 131I. Changes in tumor volume by magnetic resonance (MR) imaging were studied. RESULTS The rate of tumor induction assessed by bioluminescence imaging was 72% (68/95). Gamma counter and scintigraphy imaging analyses showed accumulation of 125I-labeled Chi dominantly in the liver. A small fraction of 125I-labeled Chi was detected in the stomach (2.02±3.07%ID) and muscle (1.37±1.48%ID) at 2 d post-treatment. Blood sample analysis showed the maximum blood concentration of 0.09±0.03%ID/mL, which peaked at 0.60±0.45 d. Over a 4-week period, 31.22±8.16%ID were excreted in the urine and 3.5±1.3% in the feces. Treatment of Chi (median, 876mm3; IQR, 496mm3-1413mm3) markedly reduced the extent of tumor growth, compared to controls (median, 12,085mm3; IQR, 7786mm3-25,832mm3; P<0.05 vs control). 131I Chi (median, 80mm3; IQR, 35mm3-172mm3; P<0.05 vs control) induced a greater tumor-suppressing effect, compared to Chi alone. CONCLUSIONS In this study, we have characterized a new radioembolization device, 131I Chi, in vivo and provided evidence for its therapeutic potential. ADVANCES IN KNOWLEDGE Transarterial embolization is a conceivable treatment option for patients with inoperable liver cancer to mitigate the disease progression. Recently, we have developed chitosan-based hydrogel microparticles. In the present study, the hydrogel microparticles were radiolabeled with 131I for treatment of liver cancer. Our results demonstrated that a hepatic arterial injection of 125I-labeled Chi resulted in substantial liver accumulation, which was accompanied by virtually no extrahepatic deposition. The results of the present study also showed that administration of 131I Chi markedly suppressed tumor growth, compared to controls and to animals receiving unlabeled Chi. 131I-labeled chitosan hydrogel microparticles represent a new therapeutic approach for treatment of liver cancer.

Development of 64Cu-NOTA-Trastuzumab for HER2 targeting: radiopharmaceutical with improved pharmacokinetics for human study

The purpose of this study was to develop 64Cu-labeled trastuzumab with improved pharmacokinetics for human epidermal growth factor receptor 2 (HER2). Methods: Trastuzumab was conjugated with SCN-Bn-NOTA and radiolabeled with 64Cu. Serum stability and immunoreactivity of 64Cu-NOTA-trastuzumab were tested. Small-animal PET imaging and biodistribution studies were performed in a HER2-positive breast cancer xenograft model (BT-474). The internal dosimetry for experimental animals was determined using the image-based approach with the Monte Carlo N-particle code. Results: 64Cu-NOTA-trastuzumab was prepared with high radiolabeling yield and radiochemical purity (>98%) and showed high stability in serum and good immunoreactivity. Uptake of 64Cu-NOTA-trastuzumab was highest at 48 h after injection as determined by PET imaging and biodistribution results in BT-474 tumors. The blood radioactivity concentrations of 64Cu-NOTA-trastuzumab decreased biexponentially with time in both mice with and mice without BT-474 tumor xenografts. The calculated absorbed dose of 64Cu-NOTA-trastuzumab was 0.048 mGy/MBq for the heart, 0.079 mGy/MBq for the liver, and 0.047 mGy/MBq for the spleen. Conclusion: 64Cu-NOTA-trastuzumab was effectively targeted to the HER2-expressing tumor in vitro and in vivo, and it exhibited a relatively low absorbed dose due to a short residence time. Therefore, 64Cu-NOTA-trastuzumab could be applied to select the right patients and right timing for HER2 therapy, to monitor the treatment response after HER2-targeted therapy, and to detect distal or metastatic spread.

Detection of metastatic tumors after γ-irradiation using longitudinal molecular imaging and gene expression profiling of metastatic tumor nodules.

A few recent reports have indicated that metastatic growth of several human cancer cells could be promoted by radiotherapy. C6-L cells expressing the firefly luciferase (fLuc) gene were implanted subcutaneously into the right thigh of BALB/c nu/nu mice. C6-L xenograft mice were treated locally with 50-Gy γ-irradiation (γ-IR) in five 10-Gy fractions. Metastatic tumors were evaluated after γ-IR by imaging techniques. Total RNA from non-irradiated primary tumor (NRPT), γ-irradiated primary tumor (RPT), and three metastatic lung nodule was isolated and analyzed by microarray. Metastatic lung nodules were detected by BLI and PET/CT after 6–9 weeks of γ-IR in 6 (17.1%) of the 35 mice. The images clearly demonstrated high [18F]FLT and [18F]FDG uptake into metastatic lung nodules. Whole mRNA expression patterns were analyzed by microarray to elucidate the changes among NRPT, RPT and metastatic lung nodules after γ-IR. In particular, expression changes in the cancer stem cell markers were highly significant in RPT. We observed the metastatic tumors after γ-IR in a tumor-bearing animal model using molecular imaging methods and analyzed the gene expression profile to elucidate genetic changes after γ-IR.

Abstract 2419: Irradiation of α-ionizing radiation to in vivo glioma model induced metastasis via occurrence of epithelial-mesenchymal transition

α-Ionizing radiation (IR) therapy is known to be a one of major therapeutic tools of cancer treatment but α-IR also could be an inducer of tumorigenesis and metastasis. Metastasis is major obstacle and required to overcome for cancer treatment. Therefore, the aim of this investigation was to study whether radiation could induce metastasis our in vivo mouse system, and molecular mechanism behind α-IR-induced metastasis. C6L transfectant cell line expressing firefly luciferase (fLuc) was treated with α-IR and then immunoblotting, zymography and invasion assay in vitro. We also used C6L transfectant cell line to construct xenograft in nude mice and then IR was irradiated to xenograft with α-IR. The irradiated xenograft-containing mice were analyzed with survival curve, measurement of tumor size, and bioluminescence imaging in vivo and ex vivo. We also analyzed metastatic foci in organ of mice with RT-PCR analysis, H & E staining and immunohistochemistry. α-IR treatment to C6L cell induced ocurrence of epithelial-mesenchymal transition (EMT) and increase of cell invasion. In irradiated xenograft-containing mice, sizes of tumor were decreased dramatically and survival rate also extended. Almost all non-irradiated xenograft-containing control mice were dead within 4 weeks. But we also observed luminescence signals in about 20.9% of α-IR treated mice. Intestine or lung of luminescence signal-detected mice contained several foci, which expressed fLuc gene and presented histological features as a cancer tissue as well as expressions of EMT markers. Taken together, these findings indicate that α-IR treatment could induce metastasis in vivo via EMT including increase of MMP activity. We also propose that construction of metastasis animal model by α-IR treatment could use drug development to block cancer metastasis and increase understandings of metastasis mechanism. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 2419. doi:1538-7445.AM2012-2419