Evidence for the role of proteoglycans in cation-mediated gene transfer.
about
Gene delivery: a single nuclear localization signal peptide is sufficient to carry DNA to the cell nucleusTargeting of Synthetic Gene Delivery SystemsNanodelivery Systems as New Tools for Immunostimulant or Vaccine Administration: Targeting the Fish Immune SystemPolymers for improving the in vivo transduction efficiency of AAV2 vectorsDifferential expression of syndecan-1 mediates cationic nanoparticle toxicity in undifferentiated versus differentiated normal human bronchial epithelial cellsExpression of N-deacetylase/sulfotransferase and 3-O-sulfotransferase in rat alveolar type II cellsInsight concerning the mechanism of therapeutic ultrasound facilitating gene delivery: increasing cell membrane permeability or interfering with intracellular pathways?Tumor lysing genetically engineered T cells loaded with multi-modal imaging agentsEffects of size and topology of DNA molecules on intracellular delivery with non-viral gene carriers.Single-particle tracking as a quantitative microscopy-based approach to unravel cell entry mechanisms of viruses and pharmaceutical nanoparticles.Nuclear targeting of macromolecular polyanions by an HIV-Tat derived peptide. Role for cell-surface proteoglycans.Synthetic polymer nanoparticle-polysaccharide interactions: a systematic study.Three-dimensional imaging of lipid gene-carriers: membrane charge density controls universal transfection behavior in lamellar cationic liposome-DNA complexesCationic liposome-DNA complexes: from liquid crystal science to gene delivery applications.The adjuvant mechanism of cationic dimethyldioctadecylammonium liposomes.A combinatorial polymer library approach yields insight into nonviral gene deliveryScFv antibody-induced translocation of cell-surface heparan sulfate proteoglycan to endocytic vesicles: evidence for heparan sulfate epitope specificity and role of both syndecan and glypican.The mechanism of polyplex internalization into cells: testing the GM1/caveolin-1 lipid raft mediated endocytosis pathway.Mechanisms of nucleotide trafficking during siRNA delivery to endothelial cells using perfluorocarbon nanoemulsions.Engineering clustered ligand binding into nonviral vectors: alphavbeta3 targeting as an example.Liposomal formulation of a methotrexate lipophilic prodrug: assessment in tumor cells and mouse T-cell leukemic lymphoma.Cationic liposomes enhance the rate of transduction by a recombinant retroviral vector in vitro and in vivo.Intracellular Distribution and Nuclear Activity of Antisense Oligonucleotides After Unassisted Uptake in Myoblasts and Differentiated Myotubes In Vitro.Short biodegradable polyamines for gene delivery and transfection of brain capillary endothelial cellsTuning PEGylation of mixed micelles to overcome intracellular and systemic siRNA delivery barriers.In vivo functional genomic studies of sterol carrier protein-2 gene in the yellow fever mosquito.Structure and structure-function studies of lipid/plasmid DNA complexes.Tuning payload delivery in tumour cylindroids using gold nanoparticles.Hydrolytic charge-reversal of PEGylated polyplexes enhances intracellular un-packaging and activity of siRNAMagnetic nanoparticle-based isolation of endocytic vesicles reveals a role of the heat shock protein GRP75 in macromolecular delivery.Surface functionalized cationic lipid-DNA complexes for gene delivery: PEGylated lamellar complexes exhibit distinct DNA-DNA interaction regimesDevelopment of targeted therapy for bladder cancer mediated by a double promoter plasmid expressing diphtheria toxin under the control of H19 and IGF2-P4 regulatory sequencesBiosynthesis of chondroitin and heparan sulfate in chinese hamster ovary cells depends on xylosyltransferase II.Amphiphilic block copolymers enhance the cellular uptake of DNA molecules through a facilitated plasma membrane transport.Decationized polyplexes as stable and safe carrier systems for improved biodistribution in systemic gene therapyLipoplexes versus nanoparticles: pDNA/siRNA delivery.Development of chitosan/heparin nanoparticle-encapsulated cytolethal distending toxin for gastric cancer therapy.Exogenous and cell surface glycosaminoglycans alter DNA delivery efficiency of arginine and lysine homopeptides in distinctly different ways.Myths concerning the use of cationic liposomes in vivo.Cationic peptide exposure enhances pulsed-electric-field-mediated membrane disruption.
P2860
Q24552019-3FE91737-1B44-4515-AD81-61AB93B96E91Q24791090-3380A65C-FAFC-4FEF-A288-F3F3D00CF2D7Q26780430-24A99363-0025-472D-83DD-0F004C0254CFQ27438107-B64730CD-7E66-4829-BB93-F2983EA47C26Q28394538-C2C4EF12-14C8-44A2-8295-F73BC64F381EQ28565243-B02C6D35-7B7C-49D8-9C02-1E95F6EDA629Q30419720-55F889EF-B25B-493B-9BB7-696F5BC664D0Q30441151-81C3D230-C64A-49CA-B9EE-6BBED6E97125Q30496595-19A2CF46-7DD0-4BA9-BD8D-9BE8EBD34486Q30502104-BAB0CA25-0372-4642-A93F-140183217DA1Q30841060-ED117A72-40AB-436B-B827-9028315117A2Q31044576-2231EA73-E450-42F8-B839-25B289836E27Q31140822-4261AFA3-B9C4-49A7-A4FA-B1DA46C0DA27Q33257608-05378D5C-6C93-401C-88AC-1AB71A7FFF70Q33273936-A1EE2510-6918-49E3-9267-E8AE9F9E56CDQ33338185-A2A6CCEE-CBDB-4988-9809-CFC81679ACA6Q33506936-833A38F5-36EF-45F5-9C39-B2856BB14220Q33677061-6C1AE221-819B-4DC5-9757-B9E8F7A829E5Q33684461-0368109A-C2EC-4436-8917-15F06E32CF00Q33713483-09ABD3A1-7C11-417F-9B70-B5F89C2DABFDQ33713627-5A2EDA30-0FC7-4F3B-8C04-69B041BFAA68Q33784090-BC270437-195D-4370-B3D0-DFA989A47F09Q33786263-EE10CC54-1A30-42D5-AC4A-8ECFB2C4F6D3Q33811724-E3793D23-1392-47C5-A209-4BC00EBE7C3DQ33816969-C051D2CA-3756-4F6F-AE1B-4A87F737CEC6Q33855484-0ECC831C-4D19-462A-BF51-BB8641D12BB7Q33889820-4D8F8FB1-3AC8-411C-8940-0855C8E1615CQ33895572-62AD246E-177B-4B4A-AF0A-2F295AEE37C3Q33918054-9569C4AD-937A-403D-8D46-74C77E2603ABQ34067982-5E3085CE-9C14-4604-A092-7F9E6073CAC7Q34184671-A5355F00-0E8B-441C-8F22-B2B322A625F8Q34467904-41AFD8A1-EB42-4432-B95B-97640F64F468Q34594698-8376B0C0-D8C7-49A0-A5B1-F849B3A8CDDEQ34609270-E1C11557-7D68-4AF7-825A-24483418488BQ34626943-5A937CDE-77A4-4A54-A361-4AC20FC22495Q34640867-BE058FE1-6C86-46FC-B73D-FC030C45C566Q34984874-E884084E-CB6B-48C8-A2EA-C2037898C938Q34998244-47998661-D5F3-45DF-9B46-C31912D2D221Q35116145-5C97080F-26C9-4CE1-9A6C-52D81195CDAFQ35132264-38117AA3-2D53-4579-B5E2-6D671CF1EB64
P2860
Evidence for the role of proteoglycans in cation-mediated gene transfer.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on October 1996
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@en
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@nl
type
label
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@en
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@nl
prefLabel
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@en
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@nl
P2860
P356
P1476
Evidence for the role of proteoglycans in cation-mediated gene transfer.
@en
P2093
Baldeschwieler JD
Mislick KA
P2860
P304
12349-12354
P356
10.1073/PNAS.93.22.12349
P407
P577
1996-10-01T00:00:00Z