Targeted Gene Delivery to Human Airway Epithelial Cells with Synthetic Vectors Incorporating Novel Targeting Peptides Selected by Phage Display

Writer, Michele; Marshall, Barry J.; Pilkington-Miksa, Michael; Barker, Susie E.; Jacobsen, Marianne C.; Kritz, Angelika; Bell, Paul C.; Lester, Douglas H.; Tabor, Alethea B.; Hailes, Helen C.; Klein, Nigel; Hart, Stephen L.

doi:10.1080/10611860410001724459

Cited by 51 publications

(45 citation statements)

References 41 publications

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“…The addition of a cell-targeting function, such as a peptide, enhances transfection efficiency of nanoparticles by a fivefold to tenfold, depending on the cell and ligand (Writer et al 2004;Hart et al 1998). In many cases, nanoparticles with targeting properties that comprise cationic components will also retain a net positive surface charge, which, if not shielded, will provide further cell-binding functions.…”

Section: Peptide Components Of Nanoparticlesmentioning

confidence: 97%

“…The first formulation of this system (LID vector) transfected bronchial epithelium in vivo with high efficiency in rats (Jenkins et al 2000), mice (Jenkins et al 2003) and pigs (Cunningham et al 2002). Recently, we have optimised the peptide sequence for transfection of human airway epithelial cells (Writer et al 2004). The selected peptide has the sequence K 16 GACSERSMNFCG, in which K 16 mediates DNA binding, and SERSMNF is a receptorbinding ligand.…”

Section: Gene Therapy For Cfmentioning

confidence: 97%

“…A new RTN formulation, LYD, comprising a peptide with the targeting domain, YGLPHKF ("peptide Y"; Writer et al 2004), and a modified cationic diether lipid with a 14-carbon alkyl tail (CH315) instead of the C18 alkyl tail of DOTMA (Table 2) used in the LID formulation, was found to transfect both rabbit aortic smooth muscle cells and primary cultures of human saphenous vein smooth muscle cells with greater efficiency than the original integrin-targeted formulation. The YGLPHKF ligand was identified in phage display, biopanning studies on epithelial cells, and its receptor is unknown (Writer et al 2004).…”

Section: Rtn Formulations For Vascular Gene Transfermentioning

confidence: 98%

“…Phage peptide display systems offer a convenient technology for identifying candidate ligands from libraries of random peptide sequences by panning on the desired protein receptor target (Koivunen et al 1993). Alternatively, phage libraries can be panned directly on the target cell type, and this approach has been used to identify target ligands for endothelial cells (Nicklin et al 2000) and airway epithelial cells (Writer et al 2004) where the selected peptides were subsequently used to target nanocomplexes to airway epithelium in vivo (Tagalakis et al 2008).…”

Section: Integrins As Receptorsmentioning

confidence: 99%

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Multifunctional nanocomplexes for gene transfer and gene therapy

Hart

2010

Cell Biol Toxicol

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DNA formulated into aggregates with polycationic reagents are referred to by a variety of terms including non-viral vectors, synthetic vectors, lipoplexes, polyplexes and more recently nanoparticles. The capacity for delivery of multiple genes, genomic-sized constructs and siRNA delivery, with a diversity of possible formulations, as well as the possibilities of improved efficiency of in vivo gene deliveries, means that nanoparticles, or nanocomplexes to reflect self-assembling systems, will be investigated with increasing vigour in the coming years. This review briefly outlines the applications and challenges for nanoparticle technologies in the field of gene therapy then focuses on the development of a specific kind of formulation, receptor-targeted nanocomplex (RTN), that we have found to be particularly useful in our gene therapy research. An overriding guiding concept that has emerged in the development of synthetic nanodelivery systems is the idea to develop formulations and structures that mimic viruses, whilst retaining the safety elements of synthetic, non-viral systems. RTNs have been optimised and developed for airway epithelial transfection, leading towards gene therapy for cystic fibrosis and for vascular transfection in vein grafts used in bypass surgery. The modular design of the RTN platform further allows for the testing of specific hypotheses relating to the structure and functional role of components in the formation of stable particles and in the transfection pathway, leading to their ultimate disassembly in the nucleus.

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Section: Peptide Components Of Nanoparticlesmentioning

confidence: 97%

Section: Gene Therapy For Cfmentioning

confidence: 97%

Section: Rtn Formulations For Vascular Gene Transfermentioning

confidence: 98%

Section: Integrins As Receptorsmentioning

confidence: 99%

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Multifunctional nanocomplexes for gene transfer and gene therapy

Hart

2010

Cell Biol Toxicol

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“…The RTN formulation comprises cationic liposomes, a receptor-targeting peptide and plasmid DNA that self-assembles electrostatically to form cationic nanoparticles of approximately 150 nm (5). We previously tested this vector system for the transfection of airway epithelial cells in vitro and in vivo in murine lungs and tracheas via instillation and nebulization (5)(6)(7). Pigs are used widely in preclinical studies, because their lung physiology and anatomy are closer to those of humans than are those of small rodents, and their size allows for regional studies of nebulized deposition within the lung after inhalation.…”

mentioning

confidence: 99%

Airway Deposition of Nebulized Gene Delivery Nanocomplexes Monitored by Radioimaging Agents

Manunta

McAnulty²,

McDowell³

et al. 2013

Am J Respir Cell Mol Biol

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Phage nanofibers in nanomedicine: Biopanning for early diagnosis, targeted therapy, and proteomics analysis

Cao

et al. 2020

WIREs Nanomed Nanobiotechnol

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Display of a peptide or protein of interest on the filamentous phage (also known as bacteriophage), a biological nanofiber, has opened a new route for disease diagnosis and therapy as well as proteomics. Earlier phage display was widely used in protein–protein or antigen–antibody studies. In recent years, its application in nanomedicine is becoming increasingly popular and encouraging. We aim to review the current status in this research direction. For better understanding, we start with a brief introduction of basic biology and structure of the filamentous phage. We present the principle of phage display and library construction method on the basis of the filamentous phage. We summarize the use of the phage displayed peptide library for selecting peptides with high affinity against cells or tissues. We then review the recent applications of the selected cell or tissue targeting peptides in developing new targeting probes and therapeutics to advance the early diagnosis and targeted therapy of different diseases in nanomedicine. We also discuss the integration of antibody phage display and modern proteomics in discovering new biomarkers or target proteins for disease diagnosis and therapy. Finally, we propose an outlook for further advancing the potential impact of phage display on future nanomedicine. This article is categorized under: Biology‐Inspired Nanomaterials > Protein and Virus‐Based Structures

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Targeted Gene Delivery to Human Airway Epithelial Cells with Synthetic Vectors Incorporating Novel Targeting Peptides Selected by Phage Display

Cited by 51 publications

References 41 publications

Multifunctional nanocomplexes for gene transfer and gene therapy

Multifunctional nanocomplexes for gene transfer and gene therapy

Airway Deposition of Nebulized Gene Delivery Nanocomplexes Monitored by Radioimaging Agents

Phage nanofibers in nanomedicine: Biopanning for early diagnosis, targeted therapy, and proteomics analysis

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