Synthesis and use of an amphiphilic dendrimer for siRNA delivery into primary immune cells

Using siRNAs to genetically manipulate immune cells is important to both basic immunological studies and therapeutic applications. However, siRNA delivery is challenging because primary immune cells are often sensitive to the delivery materials and generate immune responses. We have recently developed an amphiphilic dendrimer that is able to deliver siRNA to a variety of cells, including primary immune cells. We provide here a protocol for the synthesis of this dendrimer, as well as siRNA delivery to immune cells such as primary T and B cells, natural killer cells, macrophages, and primary microglia. The dendrimer synthesis entails straightforward click coupling followed by an amidation reaction, and the siRNA delivery protocol requires simple mixing of the siRNA and dendrimer in buffer, with subsequent application to the primary immune cells to achieve effective and functional siRNA delivery. This dendrimer-mediated siRNA delivery largely outperforms the standard electroporation technique, opening a new avenue for functional and therapeutic studies of the immune system. The whole protocol encompasses the dendrimer synthesis, which takes 10 days; the primary immune cell preparation, which takes 3-10 d, depending on the tissue source and cell type; the dendrimer-mediated siRNA delivery; and subsequent functional assays, which take an additional 3-6 d. Delivery of siRNAs to immune cells is challenging because of these cells' sensitivity to standard transfection reagents. This protocol describes how to synthesize an amphiphilic dendrimer and apply it to transfect siRNAs in a variety of primary immune cells.

Automated summary

The development of an amphiphilic dendrimer for efficient siRNA delivery to various primary immune cells represents a significant advancement in immunological research. This protocol includes dendrimer synthesis, immune cell preparation, siRNA delivery, and functional assays, with the dendrimer-mediated siRNA delivery outperforming standard electroporation techniques.