p19Arf sensitizes B16 melanoma cells to interferon-ß delivered via mesenchymal stem cells in vitro.

The immune stimulatory and anti-neoplastic functions of type I interferon have long been applied for the treatment of melanoma. However, the systemic application of high levels of this recombinant protein is often met with toxicity. An approach that provides localized, yet transient, production of type I interferon may overcome this limitation. We propose that the use of mesenchymal stem cells (MSCs) as delivery vehicles for the production of interferon-ß (IFNß) may be beneficial when applied together with our cancer gene therapy approach. In our previous studies, we have shown that adenovirus-mediated gene therapy with IFNß was especially effective in combination with p19Arf gene transfer, resulting in immunogenic cell death. Here we showed that MSCs derived from mouse adipose tissue were susceptible to transduction with adenovirus, expressed the transgene reliably, and yet were not especially sensitive to IFNß production. MSCs used to produce IFNß inhibited B16 mouse melanoma cells in a co-culture assay. Moreover, the presence of p19Arf in the B16 cells sensitizes them to the IFNß produced by the MSCs. These data represent a critical demonstration of the use of MSCs as carriers of adenovirus encoding IFNß and applied as an anti-cancer strategy in combination with p19Arf gene therapy.

p19Arf sensitizes B16 melanoma cells to interferon-β delivered via mesenchymal stem cells in vitro

The immune stimulatory and anti-neoplastic functions of type I interferon have long been applied for the treatment of melanoma. However, the systemic application of high levels of this recombinant protein is often met with toxicity. An approach that provides localized, yet transient, production of type I interferon may overcome this limitation. We propose that the use of mesenchymal stem cells (MSCs) as delivery vehicles for the production of interferon-β (IFNβ) may be beneficial when applied together with our cancer gene therapy approach. In our previous studies, we have shown that adenovirus-mediated gene therapy with IFNβ was especially effective in combination with p19Arf gene transfer, resulting in immunogenic cell death. Here we showed that MSCs derived from mouse adipose tissue were susceptible to transduction with adenovirus, expressed the transgene reliably, and yet were not especially sensitive to IFNβ production. MSCs used to produce IFNβ inhibited B16 mouse melanoma cells in a co-culture assay. Moreover, the presence of p19Arf in the B16 cells sensitizes them to the IFNβ produced by the MSCs. These data represent a critical demonstration of the use of MSCs as carriers of adenovirus encoding IFNβ and applied as an anti-cancer strategy in combination with p19Arf gene therapy.

Optimization of design and production strategies for novel adeno-associated viral display peptide libraries.

Libraries displaying random peptides on the surface of adeno-associated virus (AAV) are powerful tools for the generation of target-specific gene therapy vectors. However, for unknown reasons the success rate of AAV library screenings is variable and the influence of the production procedure has not been thoroughly evaluated. During library screenings, the capsid variants with the most favorable tropism are enriched over several selection rounds on a target of choice and identified by subsequent sequencing of the encapsidated viral genomes encoding the library capsids with targeting peptide insertions. Thus, a high capsid-genome correlation is crucial to obtain the correct information about the selected capsid variants. Producing AAV libraries by a two-step protocol with pseudotyped library transfer shuttles has been proposed as one way to ensure such a correlation. Here we show that AAV2 libraries produced by such a protocol via transfer shuttles display an unexpected additional bias in the amino-acid composition which confers increased heparin affinity and thus similarity to wildtype AAV2 tropism. This bias may fundamentally impair the intended use of AAV libraries, discouraging the use of transfer shuttles for the production of AAV libraries in the future.

Treatment of multifocal breast cancer by systemic delivery of dual-targeted adeno-associated viral vectors.

Adeno-associated viral (AAV) vectors yield high potential for clinical gene therapy but, like for other vectors systems, they frequently do not sufficiently transduce the target tissue and their unspecific tropism prevents their application for multifocal diseases such as disseminated cancer. Targeted AAV vectors have been obtained from random AAV display peptide libraries but so far, all vector variants selected from AAV libraries upon systemic administration in vivo retained some collateral tropism, frequently the heart. Here we explored, if this impediment can be overcome by microRNA-regulated transgene cassettes as the combination of library-derived capsid targeting and micro-RNA control has not been evaluated so far. We used a tumor-targeted AAV capsid variant (ESGLSQS) selected from random AAV-display peptide libraries in vivo with remaining off-target tropism toward the heart and regulated targeted transgene expression in vivo by complementary target elements for heart-specific microRNA (miRT-1d). Although this vector still maintained its strong transduction capacity for tumor target tissue after intravenous injection, transgene expression in the heart was almost completely abrogated. This strong and completely tumor-specific transgene expression was used for therapeutic gene transfer in an aggressive multifocal, transgenic, polyoma middle T-induced, murine breast cancer model. A therapeutic suicide gene, delivered systemically by this dual-targeted AAV vector to multifocal breast cancer, significantly inhibited tumor growth after one single vector administration while avoiding side effects compared with untargeted vectors.

Enteric glucagon 37 rather than pancreatic glucagon 29 stimulates glucose absorption in rat intestine.

BACKGROUND & AIMS: Glucose and galactose are absorbed by the small intestine via the sodium-dependent glucose transporter 1 (SGLT1) and fructose via the facilitated glucose transporter 5. A stimulatory effect of enteric glucagon 37 and pancreatic glucagon 29 on intestinal carbohydrate absorption has been shown. However, only glucagon 37 is released after nutrient uptake and would thus fit into a regulatory circuit of nutrient-dependent hormone release that enhances carbohydrate absorption. Therefore, the aim of the present study was to evaluate whether glucagon 37 rather than glucagon 29 is the physiological stimulus of intestinal glucose absorption. METHODS: We examined the effects of glucagon 37, glucagon 29, and dibutyryl adenosine 3',5'-cyclic monophosphate on intestinal carbohydrate absorption and hepatic glucose output in the isolated perfused small intestine, isolated enterocytes, and isolated perfused liver of the rat. RESULTS: Reciprocal dose-response curves for the effects of the two hormones in intestine and liver were demonstrated: glucagon 37 was one order of magnitude more potent than glucagon 29 in increasing intestinal absorption of glucose via the SGLT1. In contrast, glucagon 29 more efficiently stimulated hepatic glucose release. The intracellular messenger was shown to be adenosine 3',5'-cyclic monophosphate. CONCLUSIONS: Glucagon 37 rather than glucagon 29 is the physiological stimulus of intestinal glucose absorption and exerts its effect via a specific glucagon 37 receptor.