Although currently less effi cient than their viral counterparts, nonviral vectors are under intense investigation as a safer alternative for gene therapy. For successful delivery, the nonviral vector must be able to overcome many barriers to protect DNA and specifi cally deliver it for effi cient gene expression in target cells. The use of peptides as gene delivery vectors is advantageous over other nonviral agents in that they are able to achieve all of these goals. This review will focus on the application of peptides to mediate nonviral gene delivery. By examining the literature over the past 20 years, it becomes clear that no other class of biomolecules are simultaneously capable of DNA condensation, blocking metabolism, endosomal escape, nuclear localization, and receptor targeting. Based on virtually limitless diversity of peptide sequence and function information from nature, it is increasingly clear that peptide-guided gene delivery is still in its infancy.
Cationic peptides possessing a single cysteine, tryptophan, and lysine repeat were synthesized to define the minimal peptide length needed to mediate transient gene expression in mammalian cells. The N-terminal cysteine in each peptide was either alkylated or oxidatively dimerized to produce peptides possessing lysine chains of 3, 6, 8, 13, 16, 18, 26, and 36 residues. Each synthetic peptide was studied for its ability to condense plasmid DNA and compared to polylysine19 and cationic lipids to establish relative in vitro gene transfer efficiency in HepG2 and COS7 cells. Peptides with lysine repeats of 13 or more bound DNA tightly and produced condensates that decreased in mean diameter from 231 to 53 nm as lysine chain length increased. In contrast, peptides possessing 8 or fewer lysine residues were similar to polylysine19, which bound DNA weakly and produced large (0.7-3 microns) DNA condensates. The luciferase expression was elevated 1000-fold after HepG2 cells were transfected with DNA condensates prepared with alkylated Cys-Trp-Lys18 (AlkCWK18) versus polylysine19. The gene transfer efficiencies of AlkCWK18 and cationic lipids were equivalent in HepG2 cells but different by 10-fold in COS 7 cells. A 40-fold reduction in particle size and a 1000-fold amplification in transfection efficiency for AlkCWK18 DNA condensates relative to polylysine19 DNA condensates suggest a contribution from tryptophan that leads to enhanced gene transfer properties for AlkCWK18. Tryptophan-containing cationic peptides result in the formation of small DNA condensates that mediate efficient nonspecific gene transfer in mammalian cells. Due to their low toxicity, these peptides may find utility as carriers for nonspecific gene delivery or may be developed further as low molecular weight DNA condensing agents used in targeted gene delivery systems.
Concerted delivery of BMP-4, VEGF, and hBMSCs promoted greater bone formation relative to any single factor or combination of two factors. Materials systems that allows multifactorial presentation more closely mimic natural developmental processes, and these results may have important implications for bone regeneration therapeutics.
A new class of peptide gene delivery agents were developed by inserting multiple cysteine residues into short (dp 20) synthetic peptides. Substitution of one to four cysteine residues for lysine residues in Cys-TrpLys 18 resulted in low molecular weight DNA condensing peptides that spontaneously oxidize after binding to plasmid DNA to form interpeptide disulfide bonds. The stability of cross-linked peptide DNA condensates increased in proportion to the number of cysteines incorporated into the peptide. Disulfide bond formation led to a decrease in particle size relative to control peptide DNA condensates and prevented dissociation of peptide DNA condensates in concentrated sodium chloride. Cross-linked peptide DNA condensates were 5-60-fold more potent at mediating gene expression in HepG2 and COS 7 cells relative to uncross-linked peptide DNA condensates. The enhanced gene expression was dependent on the number of cysteine residues incorporated, with a peptide containing two cysteines mediating maximal gene expression. Cross-linking peptides caused elevated gene expression without increasing DNA uptake by cells, suggesting a mechanism involving intracellular release of DNA triggered by disulfide bond reduction. The results establish cross-linking peptides as a novel class of potent gene delivery agents that enhance gene expression through a new mechanism of action.A variety of nonviral gene delivery carriers have been developed and tested as in vitro transfection agents used to transiently express foreign DNA. Cationic lipids (1, 2), polylysine peptides (3-5), and cationic polymers such as polyethylenimine (6, 7) bind electrostatically to the phosphate backbone of DNA forming complexes that mediate cellular uptake of DNA in culture.As opposed to the success of these agents in vitro, attempted in vivo use has revealed many complications related to their toxicity (8), antigenicity (9), complement activation (10), solubility (11), blood compatibility (12), and stability (13). These complications relate to the size and charge of DNA carrier complexes and ultimately to the molecular characteristics of the carrier itself. High molecular weight (HMW) 1 DNA carriers can be cytotoxic (8), are able to activate the complement system (10), and can elicit an immune response (9). The size and heterogeneity of these polymers also significantly complicates region-specific derivatization with ligands or polyethylene glycol (14).To circumvent these problems, several low molecular weight (LMW) carrier peptides have been developed that mediate in vitro gene transfer as efficiently as their HMW counterparts (15-17). They offer the advantage of controlled synthesis and defined purity that then allows strategic optimization to increase expression levels and eliminate side effects.However, when analyzed for in vivo efficacy, LMW peptide DNA condensates lacked sufficient stability to survive circulation, were not able to significantly protect DNA from metabolism, and could not effect targeting (13,18). One solution to increase LMW pept...
Liquid chromatography/mass spectrometry (LC/MS)is applied to the analysis of complex mixtures of oligosaccharides obtained through the controlled, heparinase-catalyzed depolymerization of heparin. Reversedphase ion-pairing chromatography, utilizing a volatile mobile phase, results in the high resolution separation of highly sulfated, heparin-derived oligosaccharides. Simultaneous detection by UV absorbance and electrospray ionization-mass spectrometry (ESI-MS) provides important structural information on the oligosaccharide components of this mixture. Highly sensitive and easily interpretable spectra were obtained through post-column addition of tributylamine in acetonitrile. High resolution mass spectrometry afforded elemental composition of many known and previously unknown heparin-derived oligosaccharides. UV in combination with MS detection led to the identification of oligosaccharides arising from the original non-reducing end (NRE) of the heparin chain. The structural identification of these oligosaccharides provided sequence from a reading frame that begins at the non-reducing terminus of the heparin chain. Interestingly, 16 NRE oligosaccharides are observed, having both an even and an odd number of saccharide residues, most of which are not predicted based on biosynthesis or known pathways of heparin catabolism. Quantification of these NRE oligosaccharides afforded a number-averaged molecular weight consistent with that expected for the pharmaceutical heparin used in this analysis. Molecular ions could be assigned for oligosaccharides as large as a tetradecasaccharide, having a mass of 4625 Da and a net charge of ؊32. Furthermore, MS detection was demonstrated for oligosaccharides with up to 30 saccharide units having a mass of >10,000 Da and a net charge of ؊60.The structural elucidation of complex carbohydrates remains one of the most difficult challenges for chemists, often requiring the application of multiple analytical approaches (1-5). Glycosaminoglycans (GAGs), 1 and heparin in particular, have proven to be extremely difficult to analyze because of high negative charge, polydispersity, and sequence heterogeneity (6, 7). Heparin and low molecular weight heparins, prepared through the controlled chemical or enzymatic fragmentation of heparin (8), are widely used as clinical anticoagulants. Despite their medical importance, these drugs are relatively uncharacterized in terms of their chemical structure. Moreover, heparin and the structurally related heparan sulfate exhibit many additional biological activities, making them of great interest in new drug discovery (9). Numerous challenges can arise from the structural investigation of biologically active heparin oligosaccharides, particularly those in recognition systems involving specific protein-carbohydrate interactions (10, 11). Such biologically important oligosaccharides often contain rare sequences (12, 13) and are present only in minute, often picomole quantities. New derivatization methods (14, 15), chromatography (15, 16), electrophoresis-ba...
Cross-linking peptides have been developed by inserting multiple Cys residues into a 20 amino acid condensing peptide that polymerizes through disulfide bond formation when bound to DNA resulting in small, highly stable DNA condensates that mediate efficient in vitro gene transfer [McKenzie et al. (2000) J. Biol. Chem. 275, 9970-9977]. In the present study, a minimal peptide of four Lys and two terminal Cys residues was found to substitute for Cys-Trp-(Lys)(17)-Cys, resulting in DNA condensates with similar particle size and gene expression in HepG2 cells. Substitution of His for Lys residues resulted in an optimal peptide of Cys-His-(Lys)(6)-His-Cys that, in addition to the attributes described above, also provided buffering capacity to enhance in vitro gene expression in the absence of chloroquine. The reported structure-activity relationships systematically explore peptides with combinations of Lys, Cys, and His residues resulting in low molecular weight peptides with improved gene transfer properties.
A new method of determining the oligosaccharide composition of commercial glycosaminoglycan heparin is described in which heparin was first depolymerized using heparin lyase (EC 4.2.2.7), and then analysed by a single h.p.l.c. step. All 20 of the porcine and bovine heparins examined were found to contain a small number of major oligosaccharide components, which on average comprised 86% of their mass. The five most abundant oligosaccharides have defined chemical structures. Although the relative abundance of oligosaccharides varied, the heparins examined were surprisingly similar. Porcine, bovine, low-Mr, and high and low antithrombin III (ATIII)-affinity heparins, however, each had distinctly different proportions of these major oligosaccharide components. The concentrations of one of these five oligosaccharides, containing a portion of the ATIII binding site, correlated with the anticoagulant activity of the ATIII-affinity-fractionated porcine-mucosal heparins from which it was derived. An additional oligosaccharide of undetermined structure was found in significant quantities in both bovine heparin and high ATIII-affinity porcine-mucosal heparin. The correlation between oligosaccharide concentration and anticoagulant activity suggests that the oligosaccharide is derived from a structural variant of the ATIII-binding site. Finally, for the heparins examined chondroitin/dermatan sulphate formed 0.6-7.4% of their mass.
Low molecular weight homogeneous peptides were used to form peptide/DNA condensates. A peptide possessing 18 lysines was found to protect plasmid DNA from serum endonuclease and sonicative-induced degradation whereas a shorter peptide possessing 8 lysines dissociated in 0.1 M sodium chloride and failed to protect DNA from enzymatic degradation. Peptide-condensed DNA showed no change in the ratio of supercoiled to circular DNA following 100 W sonication for up to 60 s and was able to transfect HepG2 cells with equivalent efficiency as untreated condensed plasmid DNA. Alternatively, uncondensed plasmid DNA was rapidly fragmented by sonication and serum endonucleases and resulted in negligible gene expression following condensation with peptide. Cationic lipid/DNA complexes were only partially effective at stabilizing DNA in serum compared to the complete stabilization afforded by peptide/DNA condensation. These results indicate that the stabilization afforded by condensation with a peptide protects DNA during formulation and preserves its structure in serum. These functions are important to achieve optimal gene expression from a nonviral gene delivery system.
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