Kara L. Norman

Reovirus Oncolysis of Human Breast Cancer

We have previously shown that human reovirus replication is restricted to cells with an activated Ras pathway, and that reovirus could be used as an effective oncolytic agent against human glioblastoma xenografts. This study examines in more detail the feasibility of reovirus as a therapeutic for breast cancer, a subset of cancer in which direct activating mutations in the ras proto-oncogene are rare, and yet where unregulated stimulation of Ras signaling pathways is important in the pathogenesis of the disease. We demonstrate herein the efficient lysis of breast tumor-derived cell lines by the virus, whereas normal breast cells resist infection in vitro. In vivo studies of reovirus breast cancer therapy reveal that viral administration could cause tumor regression in an MDA-MB-435S mammary fat pad model in severe combined immunodeficient mice. Reovirus could also effect regression of tumors remote from the injection site in an MDA-MB-468 bilateral tumor model, raising the possibility of systemic therapy of breast cancer by the oncolytic agent. Finally, the ability of reovirus to act against primary breast tumor samples not propagated as cell lines was evaluated; we found that reovirus could indeed replicate in ex vivo surgical specimens. Overall, reovirus shows promise as a potential breast cancer therapeutic.

MicroRNAs: expression, avoidance and subversion by vertebrate viruses

MicroRNAs (miRNAs), which can be expressed in a cell-type and tissue-specific manner, can influence the activities of genes that control cell growth and differentiation. Viruses often have clear tissue tropisms, raising the possibility that cellular miRNAs might modulate their pathogenesis. In this Review, we discuss recent findings that some vertebrate viruses either encode miRNAs or subvert cellular miRNAs, and that these miRNAs participate in both the infectious and the latent phase of the viral life cycle.

Reovirus as a novel oncolytic agent

Reovirus is a double-stranded RNA-containing virus that possesses the distinctive ability to replicate in transformed cells while sparing normal cells, both in vitro and in vivo, in rodent models of cancer. The discovery of this property only arose through years of basic research on the biology of reovirus infection. Upon elucidation of the intracellular factors that govern cellular susceptibility, it became clear that reovirus Type 3 Dearing was capable of replicating in cells with an activated Ras signaling pathway, whereas normal, untransformed cells were unable to support reovirus infection (1). Because normal cells are resistant to reovirus, it is not surprising that reovirus infection in humans is usually subclinical (2, 3). Altogether, the potential impact of such findings is impressive when one considers that activating mutations in the ras genes alone contribute to more than 30% of all human cancers and that many other mutations in elements of the Ras pathway can also contribute to oncogenesis (4, 5). Recently, research using murine cancer models has revealed that this genetically unmodified laboratory strain of reovirus can indeed selectively destroy tumor cells, with no manifestations of animal morbidity or mortality (6). This has led the way to investigation into its therapeutic potential in human cancer.

Modulation of Hepatitis C virus RNA abundance and the isoprenoid biosynthesis pathway by microRNA miR-122 involves distinct mechanisms

ABSTRACT MicroRNA 122 (miR-122) promotes hepatitis C virus (HCV) RNA abundance through a direct interaction with the viral RNA and stimulates the mevalonate pathway in the animal liver. We found that overexpression of miR-122 enhanced viral RNA accumulation without affecting genes in the mevalonate pathway, such as the 3-hydroxy-3-methylglutaryl-coenzyme A reductase (HMGCR) gene. However, inhibition of miR-122 decreased both HCV RNA and HMGCR RNA with little effects on the rates of HCV and HMGCR RNA synthesis. Loss of HCV RNA could not be restored by isoprenoid intermediate metabolites. Overall, these findings suggest that miR-122 modulates viral RNA abundance independently of its effect on isoprenoid metabolism.

Toxoplasma gondii infection specifically increases the levels of key host microRNAs.

Background The apicomplexan parasite Toxoplasma gondii can infect and replicate in virtually any nucleated cell in many species of warm-blooded animals; thus, it has evolved the ability to exploit well-conserved biological processes common to its diverse hosts. Here we have investigated whether Toxoplasma modulates the levels of host microRNAs (miRNAs) during infection. Methodology/Principal Findings Using microarray profiling and a combination of conventional molecular approaches we report that Toxoplasma specifically modulates the expression of important host microRNAs during infection. We show that both the primary transcripts for miR-17∼92 and miR-106b∼25 and the pivotal miRNAs that are derived from miR-17∼92 display increased abundance in Toxoplasma-infected primary human cells; a Toxoplasma-dependent up-regulation of the miR-17∼92 promoter is at least partly responsible for this increase. The abundance of mature miR-17 family members, which are derived from these two miRNA clusters, remains unchanged in host cells infected with the closely related apicomplexan Neospora caninum; thus, the Toxoplasma-induced increase in their abundance is a highly directed process rather than a general host response to infection. Conclusions/Significance Altered levels of miR-17∼92 and miR-106b∼25 are known to play crucial roles in mammalian cell regulation and have been implicated in numerous hyperproliferative diseases although the mechanisms driving their altered expression are unknown. Hence, in addition to the implications of these findings on the host-pathogen interaction, Toxoplasma may represent a powerful probe for understanding the normal mechanisms that regulate the levels of key host miRNAs.

Not all viruses are bad guys: the case for reovirus in cancer therapy.

Efforts to improve on cancer therapy have begun to capitalize on recent advances in our understanding of tumorigenesis. Tumor-specific characteristics are being exploited to develop selective antibodies and pharmacological inhibitors that specifically target cancer cells, and these agents are already showing clinical promise. None of these approaches, however, has captured our imagination as much as the use of replication-competent viruses to kill cancer cells. Whereas normal cells resist replication, tumor cells have an impaired antiviral response that sensitizes them to oncolytic viruses. One such virus is reovirus, a benign, naturally occurring virus that can effect tumor regression in animal models. Reovirus is demonstrating much promise in pre-clinical studies of cancer therapy and in clinical trials, where a lack of toxicity and signs of efficacy are generating excitement for this novel potential cancer therapeutic.

Reovirus as an experimental therapeutic for brain and leptomeningeal metastases from breast cancer.

Brain and leptomeningeal metastases are common in breast cancer patients and our current treatments are ineffective. Reovirus type 3 is a replication competent, naturally occurring virus that usurps the activated Ras-signaling pathway (or an element thereof) of tumor cells and lyses them but leaves normal cells relatively unaffected. In this study we evaluated reovirus as an experimental therapeutic in models of central nervous system (CNS) metastasis from breast cancer. We found all breast cancer cell lines tested were susceptible to reovirus, with >50% of these cells lysed within 72 h of infection. In vivo neurotoxicity studies showed only mild local inflammation at the injection site and mild communicating hydrocephalus with neither diffuse encephalitis nor behavioral abnormalities at the therapeutically effective dose of reovirus (intracranial) (ie 107 plaque-forming units) or one dose level higher. In vivo, a single intratumoral administration of reovirus significantly reduced the size of tumors established from two human breast cancer cell lines and significantly prolonged survival. Intrathecal administration of reovirus also remarkably prolonged survival in an immunocompetent racine model of leptomeningeal metastases. These data suggest that the evaluation of reovirus as an experimental therapeutic for CNS metastases from breast cancer is warranted.

Oncolytic viruses and cancer therapy

In the hopes that a better understanding of cancer biology would allow for the development of novel, more effective therapeutics, a concerted effort over the past 20 years has focussed on the molecular mechanisms of cell growth control and tumorigenesis. Recently, there has been a renewal of interest and optimism in the field, on account of a confluence of ideas from molecular oncology and virology, leading to the development of novel virus-based therapeutics for the treatment of cancer. Viruses have been used in the past as potential cancer therapeutics; a large variety of agents have been tested, including rabies, adenovirus, paramyxovirus, Newcastle disease virus and mumps virus [1]. Although ‘responses’ have been documented, little has emerged from such trials in terms of a longstanding, oncolytic virus therapeutic mainstay. Fortunately, new technologies and insight have allowed for a re-examination of oncolytic viruses; an understanding of cancer biology and signalling, for example, has permitted the characterisation of the selectivity of viruses such as reovirus for cells with an activated Ras signalling pathway [2,3]. Discovery of the ability of adenovirus E1B protein to interact with the tumor suppressor, p53, not only helped to delineate p53’s role in cell cycle control, but also provided the foundation for the development of E1B-deleted mutants as potential cancer therapeutics [4,5]. Similarly, an awareness of herpes virus biology has permitted the engineering of non-neurovirulent mutants lacking genes necessary for * Corresponding author. Tel.: +1-403-2207548; fax: +1-4032708520. E-mail address: plee@ucalgary.ca (P.W.K. Lee).

Herpes Simplex Virus is Akt-ing in translational control

All viruses depend on the cellular protein synthesis machinery for the production of viral proteins. Thus, viruses have evolved a variety of strategies to avoid innate host responses that inhibit protein synthesis. In this issue of Genes & Development, Chuluunbaatar and colleagues (pp. 2627-2639) demonstrate that Herpes Simplex Virus-1 counteracts this response through viral kinase Us3, which mimics cellular kinase Akt to phosphorylate and repress tuberous sclerosis complex 2 (TSC2), resulting in the activation of mammalian target of rapamycin complex 1 (mTORC1) and enhancement of mRNA translation.

Hepatitis C virus' Achilles' heel – dependence on liver-specific microRNA miR-122

Hepatitis C virus (HCV) is an important human liver pathogen that has infected over 170 million people worldwide, often leading to liver cirrhosis and hepatocellular carcinoma 1. While the efficacies of novel inhibitors of the viral polymerase and protease enzymes are being explored in numerous clinical trials, current therapies against HCV infections are limited to a combined administration of pegylated interferon-α and ribavirin. However, this combination therapy has considerable side effects, which include influenza-like symptoms, depression and anemia 2. Moreover, even after 48 weeks of therapy, sustained virologic response rates are observed in only half of the patients infected with the prevalent genotype 1 HCV 2. Thus, there is a need for exploring novel therapeutic approaches that target both viral and host factors that are essential for viral growth.