The occurrence of multiple tumors in an organ heralds a rapidly fatal course. Although intravascular administration may deliver oncolytic viruses/vectors to each of these tumors, its efficiency is impeded by an antiviral activity present in complement-depleted plasma of rodents and humans. Here, this activity was shown to interact with complement in a calcium-dependent fashion, and antibody neutralization studies indicated preimmune IgM has a contributing role. Short-term exposure to cyclophosphamide (CPA) partially suppressed this activity in rodents and humans. At longer time points, cyclophosphamide also abrogated neutralizing antibody responses. Cyclophosphamide treatment of rats with large single or multiple intracerebral tumors substantially increased viral survival and propagation, leading to neoplastic regression.
Despite advances in surgical and medical therapy, glioblastoma consistently remains a fatal disease. Over the last 20 years, no significant increase in survival has been achieved for patients with this disease. The formation of abnormal tumor vasculature and glioma cell invasion along white matter tracts are believed to be the major factors responsible for the resistance of these tumors to treatment. Therefore, investigation of angiogenesis and invasion in glioblastoma is essential for the development of a curative therapy. In our report, we first reviewed certain histopathological studies that focus on angiogenesis and invasion of human malignant gliomas. Second, we considered several animal models of glioma available for studying angiogenesis and invasion, including our novel animal models. Third, we focused on the molecular aspects of glioma angiogenesis and invasion, and the key mediators of these processes. Finally, we discussed the recent and ongoing clinical trials targeting tumor angiogenesis and invasion in glioma patients. A better understanding of the mechanism of glioma angiogenesis and invasion will lead to the development of new treatment methods.
Herpes simplex virus type 1 (HSV-1) amplicons are prokaryotic plasmids containing one or more transcriptional units and two cis-acting HSV-1 sequences: a viral origin of DNA replication and a viral DNA cleavage/packaging signal. In the presence of HSV-1 "helper" functions, amplicons are replicated and packaged into HSV-1 virions. Despite recent improvements in packaging methods, stocks of amplicon vectors are still contaminated with replication-competent helper virus at a frequency of 10(-4)-10(-6). To overcome this problem, we report that: (i) genetic modifications of HSV-1 genomes can be routinely achieved in Escherichia coli, either by homologous or site-specific recombination, (ii) a novel HSV-1 bacterial artificial chromosome (fHSVDeltapacDelta27 0+), which has a deletion in the essential gene encoding ICP27 and an addition of ICP0 "stuffer" sequences to increase its size to 178 kb, supports the replication and packaging of cotransfected amplicon DNA without generating replication-competent helper virus (<1 helper virus per 10(8) TU amplicon vectors), and (iii) the resulting amplicon stocks have titers of up to 3-10 x 10(8) TU/ml after concentration. Elimination of replication-competent helper virus from HSV-1 amplicon vector stocks further improves safety in gene transfer applications.
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