TY - JOUR A1 - Haddad, Dana A1 - Socci, Nicholas A1 - Chen, Chun-Hao A1 - Chen, Nanhai G A1 - Zhang, Qian A1 - Carpenter, Susanne G A1 - Mittra, Arjun A1 - Szalay, Aladar A A1 - Fong, Yuman T1 - Molecular network, pathway, and functional analysis of-time dependent gene changes associated with pancreatic cancer susceptibility to oncolytic vaccinia virotherapy JF - Molecular Therapy — Oncolytics N2 - Background: Pancreatic cancer is a fatal disease associated with resistance to conventional therapies. This study aimed to determine changes in gene expression patterns associated with infection and susceptibility of pancreatic cancer cells to an oncolyticvaccinia virus, GLV-1h153, carrying the human sodium iodide symporter for deep tissue imaging of virotherapy. Methods: Replication and susceptibility of pancreatic adenocarcinoma PANC-1 cells to GLV-1h153 was confirmed with replication and cytotoxicity assays. PANC-1 cells were then infected with GLV-1h153 and near-synchronous infection confirmed via flow cytometry of viral-induced green fluorescent protein (GFP) expression. Six and 24 hours after infection, three samples of each time point were harvested, and gene expression patterns assessed using HG-U133A cDNA microarray chips as compared to uninfected control. Differentially expressed genes were identified using Bioconductor LIMMA statistical analysis package. A fold change of 2.0 or above was used as a cutoff, with a P value of 0.01. The gene list was then analyzed using Ingenuity Pathways Analysis software. Results: Differential gene analysis revealed a total of 12,412 up- and 11,065 downregulated genes at 6 and 24 hours postinfection with GLV-1h153 as compared to control. At 6 hours postinfection. A total of 139 genes were either up or downregulated >twofold (false discovery rate < 0.05), of which 124 were mapped by Ingenuity Pathway Analysis (IPA). By 24 hours postinfection, a total of 5,698 genes were identified and 5,563 mapped by IPA. Microarray revealed gene expression changes, with gene networks demonstrating downregulation of processes such as cell death, cell cycle, and DNA repair, and upregulation of infection mechanisms (P < 0.01). Six hours after infection, gene changes involved pathways such as HMGB-1, interleukin (IL)-2, IL-6, IL-8, janus kinase/signal tranducer and activator of transcription (JAK/STAT), interferon, and ERK 5 signaling (P < 0.01). By 24 hours, prominent pathways included P53- and Myc-induced apoptotic processes, pancreatic adenocarcinoma signaling, and phosphoinositide 3-kinase/v-akt murine thymoma vial oncogene homolog 1 (PI3/AKT) pathways. Conclusions: Our study reveals the ability to assess time-dependent changes in gene expression patterns in pancreatic cancer cells associated with infection and susceptibility to vaccinia viruses. This suggests that molecular assays may be useful to develop safer and more efficacious oncolyticvirotherapies and support the idea that these treatments may target pathways implicated in pancreatic cancer resistance to conventional therapies. KW - biochemistry Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-165855 VL - 3 ER - TY - JOUR A1 - Jun, Kyong-Hwa A1 - Gholami, Spedideh A1 - Song, Tae-Jin A1 - Au, Joyce A1 - Haddad, Dana A1 - Carson, Joshua A1 - Chen, Chun-Hao A1 - Mojica, Kelly A1 - Zanzonico, Pat A1 - Chen, Nanhai G. A1 - Zhang, Qian A1 - Szalay, Aladar A1 - Fong, Yuman T1 - A novel oncolytic viral therapy and imaging technique for gastric cancer using a genetically engineered vaccinia virus carrying the human sodium iodide symporter JF - Journal of Experimental & Clinical Cancer Research N2 - Background: Gastric cancers have poor overall survival despite recent advancements in early detection methods, endoscopic resection techniques, and chemotherapy treatments. Vaccinia viral therapy has had promising therapeutic potential for various cancers and has a great safety profile. We investigated the therapeutic efficacy of a novel genetically-engineered vaccinia virus carrying the human sodium iodide symporter (hNIS) gene, GLV-1 h153, on gastric cancers and its potential utility for imaging with Tc-99m pertechnetate scintigraphy and I-124 positron emission tomography (PET). Methods: GLV-1 h153 was tested against five human gastric cancer cell lines using cytotoxicity and standard viral plaque assays. In vivo, subcutaneous flank tumors were generated in nude mice with human gastric cancer cells, MKN-74. Tumors were subsequently injected with either GLV-1 h153 or PBS and followed for tumor growth. Tc-99m pertechnetate scintigraphy and I-124 microPET imaging were performed. Results: GFP expression, a surrogate for viral infectivity, confirmed viral infection by 24 hours. At a multiplicity of infection (MOI) of 1, GLV-1 h153 achieved > 90% cytotoxicity in MNK-74, OCUM-2MD3, and AGS over 9 days, and >70% cytotoxicity in MNK-45 and TMK-1. In vivo, GLV-1 h153 was effective in treating xenografts (p < 0.001) after 2 weeks of treatment. GLV-1 h153-infected tumors were readily imaged by Tc-99m pertechnetate scintigraphy and I-124 microPET imaging 2 days after treatment. Conclusions: GLV-1 h153 is an effective oncolytic virus expressing the hNIS protein that can efficiently regress gastric tumors and allow deep-tissue imaging. These data encourages its continued investigation in clinical settings. KW - oncolytic viral therapy KW - GLV-1 h153 KW - gastric cancer KW - human sodium iodide symporter (hNIS) KW - radioiodine therapy KW - gene therapy KW - expression KW - replication KW - stomach KW - tumors KW - surgery Y1 - 2014 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-117716 SN - 1756-9966 VL - 33 IS - 2 ER - TY - JOUR A1 - Haddad, Dana A1 - Chen, Chun-Hao A1 - Carlin, Sean A1 - Silberhumer, Gerd A1 - Chen, Nanhai G. A1 - Zhang, Qian A1 - Longo, Valerie A1 - Carpenter, Susanne G. A1 - Mittra, Arjun A1 - Carson, Joshua A1 - Au, Joyce A1 - Gonen, Mithat A1 - Zanzonico, Pat B. A1 - Szalay, Aladar A. A1 - Fong, Yuman T1 - Imaging Characteristics, Tissue Distribution, and Spread of a Novel Oncolytic Vaccinia Virus Carrying the Human Sodium Iodide Symporter JF - PLoS One N2 - Introduction: Oncolytic viruses show promise for treating cancer. However, to assess therapy and potential toxicity, a noninvasive imaging modality is needed. This study aims to determine the in vivo biodistribution, and imaging and timing characteristics of a vaccinia virus, GLV-1h153, encoding the human sodium iodide symporter (hNIS. Methods: GLV-1h153 was modified from GLV-1h68 to encode the hNIS gene. Timing of cellular uptake of radioiodide \(^{131}\)I in human pancreatic carcinoma cells PANC-1 was assessed using radiouptake assays. Viral biodistribution was determined in nude mice bearing PANC-1 xenografts, and infection in tumors confirmed histologically and optically via Green Fluorescent Protein (GFP) and bioluminescence. Timing characteristics of enhanced radiouptake in xenografts were assessed via \(^{124}\)I-positron emission tomography (PET). Detection of systemic administration of virus was investigated with both \(^{124}\)I-PET and 99m-technecium gamma-scintigraphy. Results: GLV-1h153 successfully facilitated time-dependent intracellular uptake of \(^{131}\)I in PANC-1 cells with a maximum uptake at 24 hours postinfection (P < 0.05). In vivo, biodistribution profiles revealed persistence of virus in tumors 5 weeks postinjection at 10\(^9\) plaque-forming unit (PFU)/gm tissue, with the virus mainly cleared from all other major organs. Tumor infection by GLV-1h153 was confirmed via optical imaging and histology. GLV-1h153 facilitated imaging virus replication in tumors via PET even at 8 hours post radiotracer injection, with a mean % ID/gm of 3.82 \(\pm\) 60.46 (P < 0.05) 2 days after intratumoral administration of virus, confirmed via tissue radiouptake assays. One week post systemic administration, GLV1h153-infected tumors were detected via \(^{124}\)I-PET and 99m-technecium-scintigraphy. Conclusion: GLV-1h153 is a promising oncolytic agent against pancreatic cancer with a promising biosafety profile. GLV-1h153 facilitated time-dependent hNIS-specific radiouptake in pancreatic cancer cells, facilitating detection by PET with both intratumoral and systemic administration. Therefore, GLV-1h153 is a promising candidate for the noninvasive imaging of virotherapy and warrants further study into longterm monitoring of virotherapy and potential radiocombination therapies with this treatment and imaging modality. KW - nude mice KW - pancreatic cancer KW - engineered measles-virus KW - positron-emission-tomography KW - malignant pleural mesothelioma KW - reporter gene KW - replicating adenovirus KW - NA/I symporter KW - breast cancer KW - viral therapy Y1 - 2012 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-130041 VL - 7 IS - 8 ER - TY - JOUR A1 - Haddad, Dana A1 - Chen, Nanhai G. A1 - Zhang, Qian A1 - Chen, Chun-Hao A1 - Yu, Yong A. A1 - Gonzalez, Lorena A1 - Carpenter, Susanne G. A1 - Carson, Joshua A1 - Au, Joyce A1 - Mittra, Arjun A1 - Gonen, Mithat A1 - Zanzonico, Pat B. A1 - Fong, Yuman A1 - Szalay, Aladar A. T1 - Insertion of the human sodium iodide symporter to facilitate deep tissue imaging does not alter oncolytic or replication capability of a novel vaccinia virus JF - Journal of Translational Medicine N2 - Introduction: Oncolytic viruses show promise for treating cancer. However, to assess therapeutic efficacy and potential toxicity, a noninvasive imaging modality is needed. This study aimed to determine if insertion of the human sodium iodide symporter (hNIS) cDNA as a marker for non-invasive imaging of virotherapy alters the replication and oncolytic capability of a novel vaccinia virus, GLV-1h153. Methods: GLV-1h153 was modified from parental vaccinia virus GLV-1h68 to carry hNIS via homologous recombination. GLV-1h153 was tested against human pancreatic cancer cell line PANC-1 for replication via viral plaque assays and flow cytometry. Expression and transportation of hNIS in infected cells was evaluated using Westernblot and immunofluorescence. Intracellular uptake of radioiodide was assessed using radiouptake assays. Viral cytotoxicity and tumor regression of treated PANC-1tumor xenografts in nude mice was also determined. Finally, tumor radiouptake in xenografts was assessed via positron emission tomography (PET) utilizing carrier-free (124)I radiotracer. Results: GLV-1h153 infected, replicated within, and killed PANC-1 cells as efficiently as GLV-1h68. GLV-1h153 provided dose-dependent levels of hNIS expression in infected cells. Immunofluorescence detected transport of the protein to the cell membrane prior to cell lysis, enhancing hNIS-specific radiouptake (P < 0.001). In vivo, GLV-1h153 was as safe and effective as GLV-1h68 in regressing pancreatic cancer xenografts (P < 0.001). Finally, intratumoral injection of GLV-1h153 facilitated imaging of virus replication in tumors via (124)I-PET. Conclusion: Insertion of the hNIS gene does not hinder replication or oncolytic capability of GLV-1h153, rendering this novel virus a promising new candidate for the noninvasive imaging and tracking of oncolytic viral therapy. KW - Human Sodium/Iodide symporter KW - Reporter gene KW - NA+/I-symporter KW - Nude-mice KW - Cancer KW - In-Vivo KW - Expression KW - Therapy KW - Transporter KW - GLV-1H68 Y1 - 2011 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-140847 VL - 9 IS - 36 ER - TY - THES A1 - Haddad, Dana T1 - Design of oncolytic viruses for the imaging and treatment of cancer: The vaccinia construct GLV-1h153 carrying the human sodium iodide symporter T1 - Design onkolytischer Viren zur Bildgebung und Therapie von Krebserkrankungen: Das Vaccinia-Konstrukt GLV-1h153 als Träger des menschlichen Natriumjodid Symporters N2 - Therapien mittels replikations-kompetenter onkolytischer Viren zeigten bereits vielversprechende Erfolge in klinischen Studien zur Bekämpfung verschiedener Krebserkrankungen. Die Viren sind in der Lage, sich präferentiell und selektiv in Krebszellen zu vermehren, wodurch das Tumorgewebe durch Zelllyse zerstört, das gesunde Gewebe jedoch nicht geschädigt wird. Biopsien sind zurzeit der Gold-Standard zur Überwachung onkolytischer Virus Therapien. In der präklinischen und frühen klinischen Phasen ist dies auch durchführbar, doch für weitere Studien am Menschen werden Methoden benötigt, die eine nicht-invasive Überwachung der Therapie ermöglichen. Das Nachverfolgen der Viren könnte Klinikern die Möglichkeit geben, die Verteilung der Viren im Körper nachzuverfolgen, die Effizienz und therapeutische Effekte zu korrelieren bzw. die mögliche virale Toxizität zu überwachen. Im Fokus dieser Arbeit stand die Konstruktion und das Austesten des VACV Stamms GLV-1h153, welches das Gen für den humanen Natrium-Iodid-Symporter (hNIS) kodiert, das als Reportergen für nicht-invasive bildgebende Nachverfolgung der Viren diente. Demzufolge diente das hier vorgestellte Projekt der Entwicklung von Bildgebungsverfahren, die in der onkolytischen Virustherapie eingesetzt werden können. Weiterhin sollte als weitere Strategie zur Krebsbekämpfung die Möglichkeit untersucht werden, mit Unterstützung der Viren eine gezielte Radiotherapie durchzuführen. Bei hNIS handelt es sich um ein intrinsisches Membranprotein welches den aktiven Transport und die Anreicherung von Iodid in Schilddrüsenzellen und einigen anderen Geweben vermittelt. Zudem wird das Gen, neben einigen anderen humanen Genen, bereits in präklinischen Studien als Reportergen verwendet und wurde in klinischen Studien bereits zur Darstellung von Viren in Prostata-Krebspatienten benutzt. Der Transfer des hNIS-kodierenden Gens mittels viraler Vektoren könnte es ermöglichen, dass infizierte Tumorzellen Träger-freie Radionuklidproben wie z.B. Iodid-124 (124I), Iodid-131 (131I), und 99m-Technecium Pertechtenate (99mTcO4), anreichern, welche schon lange für die Verwendung am Menschen zugelassen sind. Weitere Vorteile bei der Verwendung von hNIS als Reportergen humanen Ursprungs sind zum einen seine minimale Immunogenität und zum anderen die intrazelluläre Signalamplifikation durch die Transportfunktion des Systems. Der Stamm GLV1h153 wurde in der Pankreas-Adenokarzinom Zelllinie PANC-1 getestet. GLV-1h153 konnte diese Zellen infizieren, sich in ihnen replizieren und sie in Zellkultur schließlich ebenso effizient abtöten wie GLV-1h68. Zudem wurde eine Dosis-abhängige Expression von hNIS in infizierten Zellen nachgewiesen. Immunfluoreszenzanalysen bestätigten den erfolgreichen Transport des Proteins an die Zellmembran bevor die Zelllyse stattfand, was die Zeit- und Dosis-abhängigen Aufnahme von 131I verstärkte. In vivo war GLV-1h153, ebenso wie GLV-1h68, sicher und führte zu einer effektiven Regression der Pankreasxenograft Tumoren. Die Infektion des Tumors wurde weiterhin durch optische Bildgebung und histologische Untersuchungen bestätigt. GLV-1h153 ermöglichte weiterhin die Bildgebung von Viren in Tumoren mittels 124I-abhängiger Positronen-Emissions-Tomographie (PET) sowie 99m-Technecium Pertechnat-abhängiger (99mTcO4) Gamma Szintigraphie. Die Darstellung konnte sowohl mit intratumoral, wie auch mit intravenös applizierten Viren erfolgen, war quantitativ, und die Radiotracer konnten bis zu 24 bzw. sogar 48 h nach deren Injektion nachgewiesen werden. Die quantitative Analyse der Radionuklidaufnahme aus PET-Bildgebungsdaten korrelierte mit den Daten der Bioverteilungsdaten aus isolierten Gewebn. Autoradiographische Untersuchungen von GLV-1h153 infizierten Tumoren zeigten, dass das Vorhandensein von Viren (visualisiert durch die viral vermittelte GFP Expression), lebendes Gewebe und ausreichender Blutfluss benötigt werden, um die Aufnahme des Radiotracers in den Tumor zu erhöhen. Dosimetrische Analysen infizierter Tumoren zeigten das Potential für eine systemisch applizierte Radiotherapie des Tumors auf. So führte eine Kombination aus GLV-1h153 mit 131I-Behandlung zu geringfügig besseren therapeutischen Erfolgen, als eine alleinige Therapie mit GLV-1h153. Zusammengefasst, ist GLV-1h153 demnach ein vielversprechender Kandidat zur Behandlung von Bauchspeicheldrüsenkrebs und zur nichtinvasiven Bildgebung der viralen Therapie. Die Ergebnisse untermauern die Notwendigkeit weiterer Untersuchungen und Entwicklungen in der Langzeitverfolgung viraler Therapien sowie synergistischer Effekte einer Radioiod-Kombinationstherapie mit dieser neuen therapeutischen und bildgebenden Substanzklasse. N2 - Replication-competent oncolytic viral therapies have shown great promise preclinically and in clinical trials for the treatment of various cancers. They are able to preferentially and selectively propagate in cancer cells, consequently destroying tumor tissue via cell lysis, while leaving noncancerous tissues unharmed. Currently, biopsy is the gold standard for monitoring of viral tumor colonization and oncolysis. This may be feasible in preclinical or early clinical trials; however, a noninvasive method facilitating ongoing monitoring of viral therapy is needed for human studies. The tracking of viral delivery could give clinicians the ability to assess the biodistribution of oncolytic viruses to ensure safety and correlation with treatment efficacy. This work centers on the construction and testing of a VACV strain, GLV-1h153, carrying the human sodium iodide symporter (hNIS) as a marker gene for non-invasive tracking of virus by imaging. Thus, this project aimed to help develop imaging techniques for use in clinical trials of oncolytic viral therapy. Further, the feasibility and effectiveness of virally induced targeted radiotherapy as an anti-cancer strategy was also investigated. hNIS is an intrinsic plasma membrane protein which mediates the active transport and concentration of iodide in the thyroid gland and some extra-thyroidal tissues. It is also one of several human genes currently being used as reporters in preclinical studies and has already been used in clinical studies for imaging viral replication in prostate cancer. hNIS gene transfer via viral vector may allow infected tumor cells to concentrate several carrier-free radionuclide probes such as Iodide-124 (124I), Iodide-131 (131I), and 99m-Technecium Pertechtenate (99mTcO4), which have long been approved for human use. hNIS also has the advantage of being of human origin thus minimizing immunogenicity, and its transporter based system allows intracellular signal amplification. GLV-1h153 was tested in pancreatic adenocarcinoma cell line PANC-1. GLV-1h153 infected, replicated within, and killed PANC-1 cells in cell culture as efficiently as GLV-1h68 and provided dose-dependent levels of hNIS transgene expression in infected cells. Immunofluorescence detected successful transport of the protein to the cell membrane prior to cell lysis, which enhanced dose and time-dependent intracellular uptake of 131I. In vivo, GLV-1h153 was as safe and effective as GLV-1h68 in regressing pancreatic cancer xenografts. Tumor infection by virus was confirmed via optical imaging and histology. GLV-1h153 further facilitated deep tissue imaging of virus replication in tumors via Iodide-124I positron emission tomography (PET) as well as 99mTcO4-mediated gamma scintigraphy. This was possible with both intratumoral and intravenous injection of the virus with radiouptake retained as long as 24 and 48 hours after radiotracer injection. PET image quantitation of radiouptake in tumors was found to correlate well with tissue radiouptake counts. Autoradiography of GLV-1h153-infected tumors revealed a need for presence of virus (visualized with green fluorescent protein expression), viable tissue, and adequate blood flow to enhance radiouptake in tumors. Dosimetric analysis of uptake in infected tumors displayed potential for therapeutic doses of radiotherapy to be delivered systemically to tumors. When GLV-1h153 was combined with 131I for treatment, a modest additive effect was seen as compared to GLV-1h153 alone. Therefore, GLV-1h153 is a promising new candidate for treating pancreatic cancer and noninvasively imaging viral therapy. These findings warrant further investigation into possible long term monitoring of viral therapy, as well as synergistic or additive effects of radioiodine combined with this novel treatment and imaging modality. KW - Onkolyse KW - Vaccinia-Virus KW - Bauchspeicheldrüsenkrebs KW - Bildgebendes Verfahren KW - onkolytische Viren KW - Vaccinia Virus KW - Pankreaskrebs KW - humaner Natrium-Iodid-Symporter KW - Positronen-Emissions-Tomographie KW - gezielte Radiotherapie KW - Oncolytic Virus KW - Vaccinia Virus KW - Cancer of Pancreas KW - Human sodium iodide symporter KW - Positron Emission Tomography KW - Targeted Radiotherapy Y1 - 2011 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-56441 ER -