Polycationic reagents such as cationic lipids and poly-L-lysine are widely used for gene transfer into cells in vitro and show promise as vectors for in vivo gene therapy applications as nonviral gene transfer techniques. We have developed a novel transfection method using cationic amphiphilic ␣-helical oligopeptides with repeated sequences. Oligopeptide has the advantages of being easily designed and modified because of its simple structure. In this study, we synthesized five kinds of peptides of which the total chain length and the width of the hydrophobic region were changed. The binding of the peptides to plasmid DNA was evaluated by agarose gel electrophoresis. It was found that the long and/or hydrophobic peptides can strongly bind to the DNA. The formation of large aggregates with a 0.5-5-m diameter, which consisted of the long peptides and the DNA, was observed by electron microscopy. The transfection abilities of the peptides were determined by the expression of luciferase from its cDNA in COS-7 cells. The long peptides showed high transfection abilities. As a result, it could be said that the transfection ability of these peptides was parallel to their ability to form aggregates with DNA. Furthermore, the transfection ability was increased by the addition of chloroquine in the transfection procedure. This result indicated that the internalization of the peptide-DNA aggregates would be mediated by the endocytosis pathway.
For the purpose of achieving gene transfer into cells mediated by peptides with a short chain length, we employed two kinds of amphiphilic alpha-helix peptides, mastoparan (INLK-ALAA-LAKK-IL-NH2) obtained from wasp venom and an alpha-helix model peptide (LARL-LARL-LARL-NH2). Furthermore, to strengthen the hydrophobicity of the peptide required for the formation of the aggregates with the DNA, we modified these peptides using several lipophilic groups, i.e. acyl groups with a single chain, a dialkylcarbamoyl group and a cholesteryloxycarbonyl group. We examined the ability of the peptides and their derivatives to bind and aggregate with plasmid DNA, the structural change in the peptides caused by binding with the DNA and the in vitro gene transfer abilities into COS-7 cells. As a result, mastoparan was found to acquire the DNA binding ability by introduction of the lipophilic group. The conformational change in the peptides depended on the hydrophobicity of the introduced acyl group. The DNA complex of most lipophilic mastoparan derivatives could be incorporated into the cells via the endocytosis pathway. In the case of the helix model peptide, the acyl group with a moderate chain length was required for the formation of the aggregate which is competent for incorporation into the cells. In this study, we succeeded in giving such short peptides sufficient gene transfer ability by modifying them with some lipophilic groups. However, the influence of the modification by the lipophilic groups on the formation of aggregates with DNA and the gene transfer ability depended on the structure of the peptide portion. These results indicate that consideration of total hydrophobicity balance is needed for the design of an efficient gene carrier peptide.
To define the minimal peptide length needed for gene delivery into mammalian cells, we synthesized several peptides with shortened chain lengths from the amino-termini of the original amphiphilic peptides (4(6), Ac-LARL-LARL-LARL-LRAL-LRAL-LRAL-NH( 2,) and Hel 11-7, KLLK-LLLK-LWKK-LLKL-LK), which have been known to have gene transfer abilities into cells. Each synthetic peptide was studied for its ability to bind and aggregate with plasmid DNA and the structural change of the peptide caused by binding with the DNA to establish a relative in vitro gene transfection efficiency in COS-7 cells. As a result, the deletion of eight amino acid residues of 4(6) had little influence on their ability, whereas that of 12 amino acid residues remarkably reduced the abilities to make aggregates and transfer the DNA into the cell. In the case of the Hel 11-7 series peptides, deletion of amino acid residues caused a considerable reduction in abilities to bind and form aggregates with DNA and to transfer the DNA into cell in due order. In summary, 16 and 17 amino acid residues were sufficient to form aggregates with the DNA and transfer the DNA into the cells in the deletion series of 4(6) and Hel 11-7, respectively. Furthermore, it was indicated that reduction of membrane perturbation activity of the peptide-DNA complex due to deletion of the peptide chain length caused suppression of the transfection efficiency even if the complex was incorporated into the cells. Transfer of the complex to cytosol mediated by membrane perturbation activity of the peptide is an important step for efficient protein expression from its cDNA. The results of this study will make it easy to design and synthesize a functional gene carrier molecule such as a carbohydrate-modified peptide used in targeted gene delivery.
SummaryWe previously demonstrated the immunosuppressive activity of anti-histone H1 autoantibody induced in experimental and clinical liver allograft tolerance. This study aimed to explore the immunological aspects of anti-histone H1 autoantibody in liver injury induced by concanavalin A (Con A). To establish a Con A-hepatitis model, 20 mg/kg Con A was intravenously injected into rats, after which liver function and histopathological analyses were performed. In this model, anti-histone H1 autoantibody was transiently induced in the sera during the natural recovery stage, 3-7 days after Con A injection. To evaluate the therapeutic significance of anti-histone H1 autoantibody, a polyclonal antibody against histone H1 was intraperitoneally injected immediately after Con A injection. We found that injection of antihistone H1 antibody could reduce Con A-induced liver damage. Further mechanical analyses revealed that anti-histone H1 antibody altered the intracellular activation of mitogen-activated protein kinase, nuclear factor-jB and calcineurin via T-cell receptor signalling, suggesting that anti-histone H1 antibody may protect the liver from Con A-induced injury by inhibiting activation of effector T cells. These findings suggest that anti-histone H1 autoantibody may be a natural immune regulatory factor that protects inflamed livers suffering from autoimmune hepatitis and may lead to T-cell unresponsiveness through the selective regulation of mitogen-activated protein kinase/ nuclear factor-jB and calcineurin signalling.
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