PepFect 14, a novel cell-penetrating peptide for oligonucleotide delivery in solution and as solid formulation

Numerous human genetic diseases are caused by mutations that give rise to aberrant alternative splicing. Recently, several of these debilitating disorders have been shown to be amenable for splice-correcting oligonucleotides (SCOs) that modify splicing patterns and restore the phenotype in experimental models. However, translational approaches are required to transform SCOs into usable drug products. In this study, we present a new cell-penetrating peptide, PepFect14 (PF14), which efficiently delivers SCOs to different cell models including HeLa pLuc705 and mdx mouse myotubes; a cell culture model of Duchenne’s muscular dystrophy (DMD). Non-covalent PF14-SCO nanocomplexes induce splice-correction at rates higher than the commercially available lipid-based vector Lipofectamine™ 2000 (LF2000) and remain active in the presence of serum. Furthermore, we demonstrate the feasibility of incorporating this delivery system into solid formulations that could be suitable for several therapeutic applications. Solid dispersion technique is utilized and the formed solid formulations are as active as the freshly prepared nanocomplexes in solution even when stored at an elevated temperatures for several weeks. In contrast, LF2000 drastically loses activity after being subjected to same procedure. This shows that using PF14 is a very promising translational approach for the delivery of SCOs in different pharmaceutical forms

Molecular anatomy of adult mouse leptomeninges.

Leptomeninges, consisting of the pia mater and arachnoid, form a connective tissue investment and barrier enclosure of the brain. The exact nature of leptomeningeal cells has long been debated. In this study, we identify five molecularly distinct fibroblast-like transcriptomes in cerebral leptomeninges; link them to anatomically distinct cell types of the pia, inner arachnoid, outer arachnoid barrier, and dural border layer; and contrast them to a sixth fibroblast-like transcriptome present in the choroid plexus and median eminence. Newly identified transcriptional markers enabled molecular characterization of cell types responsible for adherence of arachnoid layers to one another and for the arachnoid barrier. These markers also proved useful in identifying the molecular features of leptomeningeal development, injury, and repair that were preserved or changed after traumatic brain injury. Together, the findings highlight the value of identifying fibroblast transcriptional subsets and their cellular locations toward advancing the understanding of leptomeningeal physiology and pathology

A molecular atlas of cell types and zonation in the brain vasculature

Cerebrovascular disease is the third most common cause of death in developed countries, but our understanding of the cells that compose the cerebral vasculature is limited. Here, using vascular single-cell transcriptomics, we provide molecular definitions for the principal types of blood vascular and vessel-associated cells in the adult mouse brain. We uncover the transcriptional basis of the gradual phenotypic change (zonation) along the arteriovenous axis and reveal unexpected cell type differences: a seamless continuum for endothelial cells versus a punctuated continuum for mural cells. We also provide insight into pericyte organotypicity and define a population of perivascular fibroblast-like cells that are present on all vessel types except capillaries. Our work illustrates the power of single-cell transcriptomics to decode the higher organizational principles of a tissue and may provide the initial chapter in a molecular encyclopaedia of the mammalian vasculature.Peer reviewe

Getting to know the cast - cellular interactions and signaling at the neurovascular unit

The neurovascular unit (NVU), consisting of endothelial cells, basement membrane, pericytes, astrocytes and microglial cells, couples local neuronal function to local cerebral blood flow and regulates transport of blood-borne molecules across the blood-brain barrier (BBB). The building blocks and the phenotype of the NVU are well-established but the intercellular signaling between the different components remains elusive. A better understanding of the cellular interactions and signaling within the NVU is critical for the development of efficient therapeutics for the treatment of a variety of brain diseases, such as brain cancer, stroke, neuroinflammation and neurodegeneration. This review gives an overview about the current in vivo knowledge of the NVU and the communication between its different cellular constituents. We also discuss the usefulness of various model organisms for studies of the brain vasculature

Design of a tumor homing cell-penetrating peptide for drug delivery

The major drawbacks with conventional cancer chemotherapy are the lack of satisfactory specificity towards tumor cells and poor antitumor activity. In order to improve these characteristics, chemotherapeutic drugs can be conjugated to targeting moieties e.g. to peptides with the ability to recognize cancer cells. We have previously reported that combining a tumor homing peptide with a cell-penetrating peptide yields a chimeric peptide with tumor cell specificity that can carry cargo molecules inside the cells. In the present study, we have used a linear breast tumor homing peptide, CREKA, in conjunction with a cell-penetrating peptide, pVEC. This new chimeric peptide, CREKA-pVEC, is more convenient to synthesize and moreover it is better in translocating cargo molecules inside cancer cells as compared to previously published PEGA-pVEC peptide. This study demonstrates that CREKA-pVEC is a suitable vehicle for targeted intracellular delivery of a DNA alkylating agent, chlorambucil, as the chlorambucil-peptide conjugate was substantially better at killing cancer cells in vitro than the anticancer drug alone. © 2008 Springer Science+Business Media, LLC

Characterization of a novel cytotoxic cell-penetrating peptide derived from p14ARF protein.

The tumor suppressor p14ARF is widely deregulated in many types of cancers and is believed to function as a failsafe mechanism, inhibiting proliferation and inducing apoptosis as cellular response to a high oncogene load. We have found that a 22-amino-acid-long peptide derived from the N-terminal part of p14ARF, denoted ARF(1-22), which has previously been shown to mimic the function of p14ARF, has cell-penetrating properties. This peptide is internalized to the same extent as the cell-penetrating peptide (CPP) TP10 and dose-dependently decreases proliferation in MCF-7 and MDA MB 231 cells. Uptake of the ARF(1-22) peptide is associated with low membrane disturbance, measured by deoxyglucose and lactate dehydrogenase (LDH) leakage, as compared to its scrambled peptide. Also, flow cytometric analysis of annexin V/propidium iodide (PI) binding and Hoechst staining of nuclei suggest that ARF(1-22) induces apoptosis, whereas scrambled or inverted peptide sequences have no effect. The ARF(1-22) peptide mainly translocates cells through endocytosis, and is found intact inside cells for at least 3 hours. To our knowledge, this is the first time a CPP having pro-apoptopic activity has been designed from a protein

A stearylated CPP for delivery of splice correcting oligonucleotides using a non-covalent co-incubation strategy.

Aberrations in splicing patterns play a significant role in several diseases, and splice correction, together with other forms of gene regulation, is consequently an emerging therapeutic target. In order to achieve successful oligonucleotide transfection, efficient delivery vectors are generally necessary. In this study we present one such vector, the chemically modified cell-penetrating peptide (CPP) TP10, for efficient delivery of a splice-correcting 2'-OMe RNA oligonucleotide. Utilizing a functional splice correction assay, we assessed the transfection efficiency of non-covalent complexes of oligonucleotides and stearylated or cysteamidated CPPs. Stearylation of the CPPs Arg9 and penetratin, as well as cysteamidation of MPG and TP10, did not improve transfection, whereas the presence of an N-terminal stearyl group on TP10 improved delivery efficiency remarkably compared to the unmodified peptide. The splice correction levels observed with stearyl-TP10 are in fact in parity with the effects seen with the commercially available transfection agent Lipofectamine 2000. However, the inherent toxicity associated with cationic lipid-based transfections can be completely eliminated when using the stearylated TP10, making this vector highly promising for non-covalent delivery of negatively charged oligonucleotides