Adipose tissue: a new target for electroporation-enhanced DNA vaccines.

DNA vaccines delivered using electroporation (EP) have had clinical success, but these EP methods generally utilize invasive needle electrodes. Here, we demonstrate the delivery and immunogenicity of a DNA vaccine into subcutaneous adipose tissue cells using noninvasive EP. Using finite element analysis, we predicted that plate electrodes, when oriented properly, could effectively concentrate the electric field within adipose tissue. In practice, these electrodes generated widespread gene expression persisting for at least 60 days in vivo within interscapular subcutaneous fat pads of guinea pigs. We then applied this adipose-EP protocol to deliver a DNA vaccine coding for an influenza antigen into guinea pigs. The resulting host immune responses elicited were of a similar magnitude to those achieved by skin delivery with EP. The onset of the humoral immune response was more rapid when the DNA dose was spread over multiple injection sites, and increasing the voltage of the EP device increased the magnitude of the immune response. This study supports further development of EP protocols delivering gene-based therapies to subcutaneous fat.

Prototype development and preclinical immunogenicity analysis of a novel minimally invasive electroporation device.

The magnitude of the immune response to a DNA vaccine depends on three criteria--the optimized vector design, the use of a suitable adjuvant and the successful delivery and subsequent expression of the plasmid in the target tissue. In vivo electroporation (EP) has proved to be particularly effective in efficiently delivering DNA immunogens to the muscle and the skin, and indeed several devices have entered into human clinical trials. Here, we report on a novel concept of DNA delivery to the dermal tissue using a minimally invasive EP device, which is powered using low-voltage parameters. We show that this prototype device containing a novel 4 × 4-electrode array results in robust and reproducible transfection of dermal tissue and subsequent antigen expression at the injection site. Using DNA encoding for NP and M2e influenza antigens, we further show induction of potent cellular responses in a mouse model as measured by antigen-specific T-cell ELISpot assays. Importantly, 100% of the immunized animals were protected when challenged with VN/1203/04 (H5N1) strain of influenza. We have also extended our findings to a guinea-pig model and demonstrated induction of HI titers greater than 1:40 against a pandemic novel H1N1 virus showing proof of concept efficacy for DNA delivery with the prototype device in a broad spectrum of species and using multiple antigens. Finally, we were able to generate protective HI titers in macaques against the same novel H1N1 strain. Our results suggest that the minimally invasive dermal device may offer a safe, tolerable and efficient method to administer DNA vaccinations in a prophylactic setting, and thus potentially represents an important new option for improved DNA vaccine delivery in vivo.

Insect renal tubules constitute a cell-autonomous immune system that protects the organism against bacterial infection.

Innate immunity is a widespread and important defence against microbial attack, which in insects is thought to originate mainly in the fat body. Here we demonstrate that the fluid-transporting Malpighian (renal) tubule of Drosophila melanogaster constitutes an autonomous immune-sensing tissue utilising the nitric oxide (NO) signalling pathway. Reverse transcriptase PCR (RT-PCR) shows that tubules express those genes encoding components of the Imd pathway. Furthermore, isolated tubules bind and respond to lipopolysaccharide (LPS), by upregulating anti-microbial peptide (diptericin) gene expression and increased bacterial killing. Excised, LPS-challenged tubules, as well as tubules from LPS-infected flies, display increased NO synthase (NOS) activity upon immune challenge. Targetted expression of a Drosophila NOS (dNOS) transgene to only principal cells of the tubule main segment using the GAL4/UAS system increases diptericin expression. In live flies, such targetted over-expression of dNOS to tubule principal cells confers increased survival of the whole animal upon E. coli challenge. Thus, we describe a novel role of Malpighian tubules in immune sensing and insect survival.

Model organisms: new insights into ion channel and transporter function. L-type calcium channels regulate epithelial fluid transport in Drosophila melanogaster.

The neuropeptide CAP2b stimulates fluid transport obligatorily via calcium entry, nitric oxide, and cGMP in Drosophila melanogaster Malpighian (renal) tubules. We have shown by RT-PCR that the Drosophila L-type calcium channel alpha1-subunit genes Dmca1D and Dmca1A (nbA) are both expressed in tubules. CAP2b-stimulated fluid transport and cytosolic calcium concentration ([Ca2+]i) increases are inhibited by the L-type calcium channel blockers verapamil and nifedipine. cGMP-stimulated fluid transport is verapamil and nifedipine sensitive. Furthermore, cGMP induces a slow [Ca2+]i increase in tubule principal cells via verapamil- and nifedipine-sensitive calcium entry; RT-PCR shows that tubules express Drosophila cyclic nucleotide-gated channel (cng). Additionally, thapsigargin-induced [Ca2+]i increase is verapamil sensitive. Phenylalkylamines bind with differing affinities to the basolateral and apical surfaces of principal cells in the main segment; however, dihydropyridine binds apically in the tubule initial segment. Immunocytochemical evidence suggests localization of alpha1-subunits to both basolateral and apical surfaces of principal cells in the tubule main segment. We suggest roles for L-type calcium channels and cGMP-mediated calcium influx in both calcium signaling and fluid transport mechanisms in Drosophila.