Enhancement of phage-mediated gene transfer by nuclear localization signal

The cell membrane and the nuclear membrane are two major barriers hindering the free movement of various macromolecules through animal cells. Nevertheless, some proteins can actively bypass these barriers by dint of intrinsic peptidic signals, so incorporation of these signals might improve the efficacy of artificial gene delivery vehicles. We examined the role of the nuclear localization signal (NLS) in gene transfer, using recombinant lambda phage as a model of the polymer/DNA complexes. We prepared a lambda phage displaying a 32-mer NLS of SV40 T antigen on its surface (NLS phage), and found that this NLS phage, delivered into the cytoplasm by appropriate devices, has higher affinity for the nucleus and induces the expression of encapsulated marker genes more efficiently than does the wild-type phage. This suggests that the 32-mer NLS peptide will become a practical tool for artificial gene delivery vehicles with enhanced nuclear targeting activity.     

In vivo gene delivery and expression by bacteriophage lambda vectors

AIMS: Bacteriophage vectors have potential as gene transfer and vaccine delivery vectors because of their low cost, safety and physical stability. However, little is known concerning phage-mediated gene transfer in mammalian hosts. We therefore performed experiments to examine phage-mediated gene transfer in vivo. METHODS AND RESULTS: Mice were inoculated with recombinant lambda phage containing a mammalian expression cassette encoding firefly luciferase (luc). Efficient, dose-dependent in vivo luc expression was detected, which peaked within 24 h of delivery and declined to undetectable levels within a week. Display of an integrin-binding peptide increased cellular internalization of phage in vitro and enhanced phage-mediated gene transfer in vivo. Finally, in vivo depletion of phagocytic cells using clodronate liposomes had only a minor effect on the efficiency of phage-mediated gene transfer. CONCLUSIONS: Unmodified lambda phage particles are capable of transducing mammalian cells in vivo, and may be taken up -- at least in part -- by nonphagocytic mechanisms. Surface modifications that enhance phage uptake result in more efficient in vivo gene transfer. SIGNIFICANCE AND IMPACT OF THE STUDY: These experiments shed light on the mechanisms involved in phage-mediated gene transfer in vivo, and suggest new approaches that may enhance the efficiency of this process.     

A novel peptide, THALWHT, for the targeting of human airway epithelia

Targeting gene vectors to human airway epithelial cells may help to overcome the current inefficiency of gene transfer as the major problem confronting cystic fibrosis gene therapy. To elucidate novel ligands targeting abundant, apically located receptors on airway epithelial cells, a phage display library was screened for peptides binding with high affinity to such cells. This screening yielded a selectively enriched amino acid sequence, Thr-His-Ala-Leu-Trp-His-Thr (THALWHT). Subsequent binding studies confirmed that THALWHT-displaying phages bound much stronger than phages displaying control peptides to human airway epithelial cells. In contrast, no significant binding differences were observed on a variety of non-airway-derived human cell lines suggesting selective binding of the THALWHT motif to airway epithelia. Confocal microscopy of such cells after exposure to labelled synthetic THALWHT peptide indicated that its binding is followed by specific internalisation via endocytosis. A synthetic peptide comprising a cyclic CTHALWHTC domain and a DNA binding moiety enabled efficient targeted gene delivery into human airway epithelial cells. Competition assays with free THALWHT peptide confirmed the specificity of gene delivery. Thus, the THALWHT motif may prove a useful targeting moiety for both non-viral and viral gene therapy vectors.     

Gene transfer to mammalian cells using genetically targeted filamentous bacteriophage.

We have genetically modified filamentous bacteriophage to deliver genes to mammalian cells. In previous studies we showed that noncovalently attached fibroblast growth factor (FGF2) can target bacteriophage to COS-1 cells, resulting in receptor-mediated transduction with a reporter gene. Thus, bacteriophage, which normally lack tropism for mammalian cells, can be adapted for mammalian cell gene transfer. To determine the potential of using phage-mediated gene transfer as a novel display phage screening strategy, we transfected COS-1 cells with phage that were engineered to display FGF2 on their surface coat as a fusion to the minor coat protein, pIII. Immunoblot and ELISA analysis confirmed the presence of FGF2 on the phage coat. Significant transduction was obtained in COS-1 cells with the targeted FGF2-phage compared with the nontargeted parent phage. Specificity was demonstrated by successful inhibition of transduction in the presence of excess free FGF2. Having demonstrated mammalian cell transduction by phage displaying a known gene targeting ligand, it is now feasible to apply phage-mediated transduction as a screen for discovering novel ligands.     

Recombinant λ-phage nanobioparticles for tumor therapy in mice models

Lambda phages have considerable potential as gene delivery vehicles due to their genetic tractability, low cost, safety and physical characteristics in comparison to other nanocarriers and gene porters. Little is known concerning lambda phage-mediated gene transfer and expression in mammalian hosts. We therefore performed experiments to evaluate lambda-ZAP bacteriophage-mediated gene transfer and expression in vitro. For this purpose, we constructed recombinant λ-phage nanobioparticles containing a mammalian expression cassette encoding enhanced green fluorescent protein (EGFP) and E7 gene of human papillomavirus type 16 (λ-HPV-16 E7) using Lambda ZAP- CMV XR vector. Four cell lines (COS-7, CHO, TC-1 and HEK-239) were transduced with the nanobioparticles. We also characterized the therapeutic anti-tumor effects of the recombinant λ-HPV-16 E7 phage in C57BL/6 tumor mice model as a cancer vaccine. Obtained results showed that delivery and expression of these genes in fibroblastic cells (COS-7 and CHO) are more efficient than epithelial cells (TC-1 and HEK-239) using these nanobioparticles. Despite the same phage M.O.I entry, the internalizing titers of COS-7 and CHO cells were more than TC-1 and HEK-293 cells, respectively. Mice vaccinated with λ-HPV-16 E7 are able to generate potent therapeutic antitumor effects against challenge with E7- expressing tumor cell line, TC-1 compared to group treated with the wild phage. The results demonstrated that the recombinant λ-phages, due to their capabilities in transducing mammalian cells, can also be considered in design and construction of novel and safe phage-based nanomedicines.     

Evidence for a plasma membrane-mediated permeability barrier to Tat basic domain in well-differentiated epithelial cells: lack of correlation with heparan sulfate

Membrane permeation peptides, such as Tat basic domain, have emerged as useful membrane transduction agents with potential utility in therapeutic delivery and diagnostic imaging. While generally thought to universally permeate all cells by a nonselective process, the mechanism of membrane transduction remains poorly characterized. To examine vectorial transport properties of Tat basic domain in well-differentiated epithelial cells possessing tight junctions, L and D stereoisomers of Tat(48-57) peptide conjugates labeled with (99m)Tc were quantitatively analyzed in confluent monolayers of MDCK renal epithelial and CaCo-2 colonic carcinoma cells grown in transwell configurations. In both cell lines, vectorial transepithelial apparent permeability coefficients (P(app)) for L- and D-[(99m)Tc]Tat-peptides ranged from 30 to 70 nm/s, comparable to values for the macromolecular impermeant marker inulin in both apical-to-basolateral and basolateral-to-apical directions, but 100-fold less than the P(app) values for propranolol, a highly permeable control compound. Upon direct instillation of [(99m)Tc]Tat-peptide into the urinary bladder of living rats in vivo, no transepithelial permeation into other tissues was identified. Furthermore, MDCK and CaCo-2 cells showed a complete lack of intracellular accumulation of fluorescein conjugated Tat-peptide. However, translocation into cells was induced by treatment with plasma membrane permeabilizing agents such as digitonin and acetone/methanol, while cholesterol depletion with beta-methyl-cyclodextrin and metabolic inhibition with CCCP or 4 degrees C showed no effect. By contrast, in Hela and KB 3-1 cells, epithelial lines that do not form tight junctions in monolayer culture, baseline cytoplasmic and nucleolar accumulation was readily observed. Because all four cell lines expressed heparan sulfate proteoglycans, putative receptors for Tat basic peptides, we found no correlation between heparan sulfate and the permeation barrier observed in MDCK and CaCo-2 cells. The unanticipated presence of a permeation barrier to Tat-peptides in well-differentiated epithelial cells suggests the existence of cell-specific mechanisms for mediated translocation of these permeation peptides.     

Enhancement of gene delivery using novel homodimeric tat peptide formed by disulfide bond

Cationic liposomes have been actively used as gene delivery vehicle because of their minimal toxicity, but their relatively low efficiency of gene delivery is the major disadvantage of these vectors. Recently, cysteine residue incorporation to HIV-1 Tat peptide increased liposomemediated transfection compared with unmodified Tat peptide. Therefore, we designed a novel modified Tat peptide having a homodimeric (Tat-CTHD, Tat-NTHD) and closed structure (cyclic Tat) simply by using the disulfide bond between cysteines to develop a more efficient and safe nonviral gene delivery system. The mixing of Tat-CTHD and Tat-NTHD with DNA before mixing with lipofectamine increased the transfection efficiency compared with unmodified Tat peptide and lipofectamine only in MCF-7 breast cancer cells and rat vascular smooth muscle cells. However, cyclic Tat did not show any improvement in the transfection efficiency. In the gel retardation assay, Tat-CTHD and Tat-NTHD showed more strong binding with DNA than unmodified Tat and cyclic Tat peptide. This enhancement was only shown when Tat-CTHD and Tat-NTHD were mixed with DNA before mixing with lipofectamine. The effects of Tat- CTHD and Tat-NTHD were also valid in the experiment using DOTAP and DMRIE instead of lipofectamine. We could not find any significant cytotoxicity in the working concentration and more usage of these peptides. In conclusion, we have designed a novel transfection-enhancing peptide by easy homodimerization of Tat peptide, and the simple mix of these novel peptides with DNA increased the gene transfer of cationic lipids more efficiently with no additional cytotoxicity.     

Tat碱性结构域-Bcl-Xs融合蛋白与细胞短暂共培养可诱导细胞程序性死亡

艾滋病毒的 Tat蛋白碱性结构域的 1 3个氨基酸的多肽能自主穿越细胞膜并将与之融合表达的其他蛋白带入细胞 .为探讨融合表达的蛋白是否可保持原有的主要生物学功能 ,将 Bcl- Xs蛋白与 Tat碱性结构域在大肠杆菌中融合表达 ,重组蛋白 Tat- Bcl- Xs与 CHO、CNE、Hela和 772 1细胞共温育一段时间后 ,细胞均可见明显生长抑制 ,同时细胞变圆、变小、细胞核收缩 ,并有染色体凝聚、边缘化 ,或细胞核分裂为小核的现象 ,同时出现梯状 DNA,为较典型的细胞程序性死亡 ( PCD)表现 .同时发现放线菌素 D、雷公藤内脂醇与 Tat- Bcl- Xs在诱导细胞 PCD时存在交互作用 .提示Tat- Bcl- Xs蛋白可自主进入细胞内 ,并保持了 Bcl- Xs蛋白的 PCD诱导作用 ,初步证实了利用 Tat碱性结构域进行药物设计的可行性 ,同时也提示 Tat- Bcl- Xs蛋白可能可作为多种药物联合治疗中的一员而在抗肿瘤治疗中发挥作用     

Genetic selection of phage engineered for receptor-mediated gene transfer to mammalian cells.

Although phage display is a powerful way of selecting ligands against purified target proteins, it is less effective for selecting functional ligands for complex targets like living cells. Accordingly, phage display has had limited utility in the development of targeting agents for gene therapy vectors. By adapting a filamentous bacteriophage for gene delivery to mammalian cells, however, we show here that it is possible to screen phage libraries for functional ligands capable of delivering DNA to cells. For example, when targeted with epidermal growth factor (EGF), M13 bacteriophage were capable of delivering a green fluorescent protein (GFP) gene to EGF receptor bearing cells in a ligand-, time-, and phage concentration-dependent manner. The EGF-targeted phage transduced COS-1 cells in a highly specific manner as demonstrated by competition with excess free EGF or alternatively with anti-EGF receptor antibodies. We further demonstrate that EGF-phage can be selected, by their ability to transduce EGF receptor bearing cells from libraries of peptide display phage. When phage were incubated with COS-1 cells, EGF ligand-encoding sequences were recovered by PCR from FACsorted, GFP-positive cells and the EGF-displaying phage were enriched 1 million-fold by four rounds of selection. These data suggest the feasibility of applying molecular evolution to phage gene delivery to select novel cell-specific DNA-targeting ligands. The same approach could be used to select genetically altered phage that are specifically designed and evolved as gene therapy vectors.