6 research outputs found
Photoinduced Endosomal Escape Mechanism: A View from Photochemical Internalization Mediated by CPP-Photosensitizer Conjugates
Endosomal escape in cell-penetrating peptide (CPP)-based drug/macromolecule delivery systems is frequently insufficient. The CPP-fused molecules tend to remain trapped inside endosomes and end up being degraded rather than delivered into the cytosol. One of the methods for endosomal escape of CPP-fused molecules is photochemical internalization (PCI), which is based on the use of light and a photosensitizer and relies on photoinduced endosomal membrane destabilization to release the cargo molecule. Currently, it remains unclear how this delivery strategy behaves after photostimulation. Recent findings, including our studies using CPP-cargo-photosensitizer conjugates, have shed light on the photoinduced endosomal escape mechanism. In this review, we discuss the structural design of CPP-photosensitizer and CPP-cargo-photosensitizer conjugates, and the PCI mechanism underlying their application
Photo-dependent cytosolic delivery of shRNA into a single blastomere in a mouse embryo
Abstract Single-cell-specific delivery of small RNAs, such as short hairpin RNA (shRNA) and small noncoding RNAs, allows us to elucidate the roles of specific upregulation of RNA expression and RNAi-mediated gene suppression in early embryo development. The photoinduced cytosolic dispersion of RNA (PCDR) method that we previously reported can introduce small RNAs into the cytosol of photoirradiated cells and enable RNA delivery into a single-cell in a spatiotemporally specific manner. However, the PCDR method has only been applied to planer cultured cells and not to embryos. This study demonstrated that the PCDR method can be utilized for photo-dependent cytosolic shRNA delivery into a single blastomere and for single blastomere-specific RNA interference in mouse embryos. Our results indicate that PCDR is a promising approach for studying the developmental process of early embryogenesis
Red and Near-Infrared Light-Directed Cytosolic Delivery of Two Different RNAs Using Photosensitive RNA Carriers
Many
cellular events are thought to be controlled by the temporal
upregulation of multiple RNAs; the timing of the upregulation of these
RNAs is not always the same. In this study, we first show that our
light-directed intracellular RNA delivery method induced high concentrations
of RNA in a short period. This effect was beneficial for the temporal
control of cellular events by functional RNAs. Next, we stimulated
the short-term upregulation of two different RNAs at different time
points. Cytosolic delivery of a first RNA was induced by red light;
thereafter, cytosolic delivery of a second RNA was induced by near-infrared
light. The time difference between the introduction of the first and
second RNA can be short (0.5–4 h) or long (>8 h). This strategy
shows the potential for future applications of the deliberate control
of time-dependent RNA concentration to guide various cellular functions
by multiple RNAs