Alternative splice forms of CTLA-4 induced by antisense mediated splice-switching influences autoimmune diabetes susceptibility in NOD mice.

Activated and regulatory T cells express the negative co-stimulatory molecule cytotoxic T-lymphocyte-associated antigen-4 (CTLA-4) that binds B7 on antigen-presenting cells to mediate cellular responses. Single nucleotide polymorphisms in the CTLA-4 gene have been found to affect alternative splicing and are linked to autoimmune disease susceptibility or resistance. Increased expression of a soluble splice form (sCTLA-4), lacking the transmembrane domain encoded by exon 3, has been shown to accelerate autoimmune pathology. In contrast, an exon 2-deficient form lacking the B7 ligand binding domain (liCTLA-4), expressed by diabetes resistant mouse strains has been shown to be protective when expressed as a transgene in diabetes susceptible non-obese diabetic (NOD) mice. We sought to employ an antisense-targeted splice-switching approach to independently produce these CTLA-4 splice forms in NOD mouse T cells and observe their relative impact on spontaneous autoimmune diabetes susceptibility. In vitro antisense targeting of the splice acceptor site for exon 2 produced liCTLA-4 while targeting exon 3 produced the sCTLA-4 form in NOD T cells. The liCTLA-4 expressing T cells exhibited reduced activation, proliferation and increased adhesion to intercellular adhesion molecule-1 (ICAM-1) similar to treatment with agonist α-CTLA-4. Mice treated to produce liCTLA-4 at the time of elevated blood glucose levels exhibited a significant reduction in the incidence of insulitis and diabetes, whereas a marked increase in the incidence of both was observed in animals treated to produce sCTLA-4. These findings provide further support that alternative splice forms of CTLA-4 affects diabetes susceptibility in NOD mice and demonstrates the therapeutic utility of antisense mediated splice-switching for modulating immune responses.

Development of novel bioanalytical methods to determine the effective concentrations of phosphorodiamidate morpholino oligomers in tissues and cells.

Phosphorodiamidate morpholino oligomers (PMO) are neutrally charged, sequence-specific antisense agents that interfere with targeted gene expression. PMO have been shown to be highly specific and potent therapies after cellular uptake, yet methods to detect PMO in tissue and inside the cell are limited. We offer in this report novel methods for the detection of cellular resident PMO using flow cytometry-fluorescence in situ hybridization (flow FISH) and a sandwich hybridization technique to quickly and sensitively quantify tissue resident PMO. These methods rely on oligonucleotide probes complementary to a PMO to specifically detect and quantify cell-associated and tissue resident PMO after in vitro or in vivo administration. Using the sandwich hybridization technique, we show that intranasally delivered PMO demonstrates zero-order clearance kinetics from the lung. Furthermore, PMO was detected in nonhematopoietic and hematopoietic cells of the lung regardless of influenza virus infection, although an increase in PMO uptake in infected hematopoietic cells was observed. Coincident measurement of target knock-down to cell-associated influenza A PMO concentration allowed for the calculation of an EC50.