Knockdown of mouse VCAM-1 by vector-based siRNA.

Graft rejection is critically dependent on the recruitment of leukocytes via adhesion molecules on the endothelium, and inhibition of these interactions can prolong graft survival. We have therefore developed an approach using siRNA to inhibit the expression of VCAM-1 in endothelial cells. We transfected siRNA constructs into murine corneal and vascular endothelium and looked at expression of VCAM-1 and other surface molecules by flow cytometry. Adhesion assays (both static and under flow) were used to determine the effect of VCAM-1 inhibition. The activation of cellular stress responses was assessed by RT-PCR. Constructs encoding siRNA can block expression of VCAM-1 in both corneal and vascular endothelial cells (in the latter case after cytokine stimulation). Inhibition of VCAM-1 expression reduced the ability of T cells to adhere to endothelium. However, there were non-specific effects of siRNA expression, including upregulation of (Programmed Death Ligand 1) PDL1 and decreased cell growth. Analysis of stress pathways showed that the endothelial cells transfected with siRNA had upregulated molecules associated with cell stress. While these data are supportive of a potential therapeutic role for siRNA constructs in blocking the expression of adhesion molecules, they also highlight potential non-specific effects of siRNA that must be carefully considered in any application of this technology.

Effect of vectors on human endothelial cell signal transduction: implications for cardiovascular gene therapy.

OBJECTIVE: Endothelium is an important target for gene therapy. We have investigated the effect of viral and nonviral vectors on the phenotype and function of endothelial cells (ECs) and developed methods to block any activation caused by these vectors. METHODS AND RESULTS: Transduction of ECs with viral vectors, including adenovirus, lentiviruses, and Moloney murine leukemia virus, can induce a pro-inflammatory phenotype. This activation was reduced when nonviral vectors were used. We demonstrate that after transduction there is upregulation of dsRNA-triggered antiviral and PI3K/Akt signaling pathway. Blockade of the NFkappaB, PI3-K, or PKR signaling pathways all operated to inhibit partially virally induced activation, and inhibition of both PKR and PI3-K pathways totally blocked EC activation. Furthermore, inhibition of IFN-alpha/beta in addition to PI3-K was effective at preventing EC activation. CONCLUSIONS: Viral vectors, although efficient at transducing ECs, result in their activation. Blockade of the signaling pathways involved in viral activation may be used to prevent such activation.