Oligomers of the arginine-rich motif of the HIV-1 TAT protein are capable of transferring plasmid DNA into cells

We constructed multimers of the TAT-(47-57) peptide. This polycationic peptide is known to be a protein and particle transduction domain and at the same time to comprise a nuclear localization function. Here we show that oligomers of the TAT-(47-57) peptide compact plasmid DNA to nanometric particles and stabilize DNA toward nuclease degradation. At optimized vector compositions, these peptides mediated gene delivery to cells in culture 6-8-fold more efficiently than poly-L-arginine or the mutant TAT(2)-M1. When DNA was precompacted with TAT peptides and polyethyleneimine (PEI), Superfect, or LipofectAMINE was added, transfection efficiency was enhanced up to 390-fold compared with the standard vectors. As early as after 4 h of transfection, reporter gene expression mediated by TAT-containing complexes was higher than the 24-h transfection level achieved with a standard PEI transfection. When cells were cell cycle-arrested by serum starvation or aphidicolin, TAT-mediated transfection was 3-fold more efficient than a standard PEI transfection in proliferating cells. In primary nasal epithelial cells and upon intratracheal instillation in vivo, TAT-containing complexes were superior to standard PEI vectors. These data together with confocal imaging of TAT-DNA complexes in cells support the hypothesis that the TAT nuclear localization sequence function is involved in enhancing gene transfer.     

Targeted delivery in breast cancer cells via iodine: nuclear localization sequence conjugate

The nonviral vector with iodine-nuclear localization sequence (namely, NLS-I) targeting breast cancer cells was fabricated. Ternary complexes were formed via charge interactions among NLS-I peptides, PEI 1800, and DNA, and we investigated their cellular internalization, nuclear accumulation as well as transfection efficiency. All the experiments were assessed by employing MCF-7 cells that express sodium/iodide symporter and HeLa cells that lack the expression of the symporter. In MCF-7 cells, cell internalization and nuclear accumulation of NLS-I was markedly increased compared to that in NLS. In addition, compared to that of the PEI1800/DNA complex, PEI1800/DNA/NLS-I complexes exhibited much enhanced luciferase reporter gene expression by up to 130-fold. By contrast, in HeLa cells, the evident improvements of cellular internalization, nuclear accumulation, and transfection efficiency by NLS-I were not observed. This study demonstrates an alternative method to construct a nonviral delivery system for targeted gene transfer into breast cancer cells.     

Noncovalently linked nuclear localization peptides for enhanced calcium phosphate transfection

The generation of cell lines stably expressing recombinant material is a lengthy process and there has thus been much interest in the use of transient expression systems to rapidly produce recombinant material. To achieve this, the DNA of interest must be delivered into the nucleus of the target cell. The mechanisms by which this process occurs are poorly understood and the efficiency of various methods differs widely. Recently, nuclear localization signals (NLSs) have been investigated to target entry of DNA into the nucleus of mammalian cells. We have used NLSs from the SV40 and Tat antigens mixed with our model luciferase reporter gene plasmid for the transfection of Chinese hamster ovary (CHO) cells using calcium phosphate and FuGNE 6 transfection technology. The nocovalent complexation of NLSs with plasmid DNA before calcium phosphate-mediated transfection resulted in enhanced reporter gene expression with increasing ratios of NLS to plasmid until reaching a mximum. At higher ratios than maximum expression, the expression levels decreased. On the other hand, when using FuGENE 6 reagent NLSs did not enhance reporter gene expression. Cell cycle arrest in G₂/M phase obliterated the effect of the NLS on reporter gene expression when using the calcium phosphate transfection method.     

Recombinant derivatives of the human high-mobility group protein HMGB2 mediate efficient nonviral gene delivery

Certain natural peptides and proteins of mammalian origin are able to bind and condense plasmid DNA, a prerequisite for the formation of transfection-competent complexes that facilitate nonviral gene delivery. Here we have generated recombinant derivatives of the human high-mobility group (HMG) protein HMGB2 and investigated their potential as novel protein-based transfection reagents. A truncated form of HMGB2 encompassing amino acids 1-186 of the molecule was expressed in Escherichia coli at high yield. This HMGB2186 protein purified from bacterial lysates was able to condense plasmid DNA in a concentration-dependent manner, and mediated gene delivery into different established tumor cell lines more efficiently than poly(l-lysine). By attaching, via gene fusion, additional functional domains such as the HIV-1 TAT protein transduction domain (TAT(PTD)-HMGB2186), the nuclear localization sequence of the simian virus 40 (SV40) large T-antigen (SV40(NLS)-HMGB2186), or the importin-beta-binding domain (IBB) of human importin-alpha (IBB-HMGB2186), chimeric fusion proteins were produced which displayed markedly improved transfection efficiency. Addition of chloroquine strongly enhanced gene transfer by all four HMGB2186 derivatives studied, indicating cellular uptake of protein-DNA complexes via endocytosis. The IBB-HMGB2186 molecule in the presence of the endosomolytic reagent was the most effective. Our results show that recombinant derivatives of human HMGB2 facilitate efficient nonviral gene delivery and may become useful reagents for applications in gene therapy.     

Self-assembled terplexes for targeted gene delivery with improved transfection

To improve transfection efficiency and to incorporate target ligands to the gene delivery systems, heparin and heparin-biotin were introduced to complexes of polyamidoamine dendrimer and DNA (PAMAM/DNA) via electrostatic interactions to form self-assembled PAMAM/DNA/heparin and PAMAM/DNA/heparin-biotin terplexes, respectively. The self-assembled terplexes were characterized by agarose gel electrophoresis and particle size analysis. The MTT assay indicated that, after incorporation of heparin and heparin-biotin, the terplexes exhibited decreased cytotoxicity. In addition, as compared with PAMAM/DNA and PAMAM/DNA/heparin complexes, the PAMAM/DNA/heparin-biotin complexes exhibited much higher cellular uptake into HeLa cells due to the specific interactions between biotin and biotin receptors on HeLa cells, which led to the enhanced transfection activity. The PAMAM/DNA/heparin-biotin complexes would be a promising targeting gene delivery system.     

Recombinant fusion proteins TAT-Mu, Mu and Mu-Mu mediate efficient non-viral gene delivery

BACKGROUND: The inherent ability of certain peptides or proteins of viral, prokaryotic and eukaryotic origin to bind DNA was used to generate novel peptide-based DNA delivery protocols. We have developed a recombinant approach to make fusion proteins with motifs for DNA-binding ability, Mu and membrane transduction domains, TAT, and tested them for their DNA-binding, uptake and transfection efficiencies. In one of the constructs, the recombinant plasmid was designed to encode the Mu moiety of sequence MRRAHHRRRRASHRRMRGG in-frame with TAT of sequence YGRKKRRQRRR to generate TAT-Mu, while the other two constructs, Mu and Mu-Mu, harbor a single copy or two copies of the Mu moiety. METHODS: Recombinant his-tag fusion proteins TAT-Mu, Mu and Mu-Mu were purified by overexpression of plasmid constructs using cobalt-based affinity resins. The peptides were characterized for their size and interaction with DNA, complexed with plasmid pCMVbeta-gal, and shown to transfect MCF-7, COS and CHOK-1 cells efficiently. RESULTS: Recombinant fusion proteins TAT-Mu, Mu and Mu-Mu were cloned and overexpressed in BL21(DE3)pLysS with greater than 95% purity. The molecular weight of TAT-Mu was determined by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) to be 11.34 kDa while those of Mu and Mu-Mu were 7.78 and 9.83 kDa, respectively. Live uptake analysis of TAT-Mu, Mu and Mu-Mu as DP (DNA+peptide) or DPL (DNA+peptide+lipid) complexes into MCF-7 cells, followed by immunostaining and laser scanning confocal microscopy, demonstrated that the complexes are internalized very efficiently and localized in the nucleus. DNA:peptide complexes (DP) transfect MCF-7, COS and CHOK-1 cells. The addition of cationic liposomes enhances the uptake of the ternary complexes (DPL) further and also brings about 3-7-fold enhancement in reporter gene expression compared to DP alone. CONCLUSIONS: Recombinant proteins that are heterologous fusions, having DNA-binding domains and nuclear localization epitopes, generated in this study have considerable potential to facilitate DNA delivery and enhance transfection. The domains in these fusion proteins would be promising in the development of non-viral gene delivery vectors particularly in cells that do not divide.     

Arginine-rich cross-linking peptides with different SV40 nuclear localization signal content as vectors for intranuclear DNA delivery

The major barriers for intracellular DNA transportation by cationic polymers are their toxicity, poor endosomal escape and inefficient nuclear uptake. Therefore, we designed novel modular peptide-based carriers modified with SV40 nuclear localization signal (NLS). Core peptide consists of arginine, histidine and cysteine residues for DNA condensation, endosomal escape promotion and interpeptide cross-linking, respectively. We investigated three polyplexes with different NLS content (10?mol%, 50?mol% and 90?mol% of SV40 NLS) as vectors for intranuclear DNA delivery. All carriers tested were able to condense DNA, to protect it from DNAase I and were not toxic to the cells. We observed that cell cycle arrest by hydroxyurea did not affect transfection efficacy of NLS-modified carriers which we confirmed using quantitative confocal microscopy analysis. Overall, peptide carrier modified with 90?mol% of SV40 NLS provided efficient transfection and nuclear uptake in non-dividing cells. Thus, incorporation of NLS into arginine-rich cross-linking peptides is an adequate approach to the development of efficient intranuclear gene delivery vehicles.     

Improvement of exogenous DNA nuclear importation by nuclear localization signal‐bearing vectors: a promising way for non‐viral gene therapy?

Several vectors have been developed in order to target genes to specific cells. Virus-based vectors lead to a high transfection efficiency in vitro, but display important disadvantages such as pathological risks, which they expose to patients. Plasmid-associated chemical vectors lack these disadvantages, but allow only a very low efficiency of transgene expression. Most of the non-viral-based gene transfer techniques developed until now mainly focused their efforts to overcome the problem of DNA entry into the cell. Some recent works, however, have begun to investigate the nucleus entry problem and suggest that the trafficking of DNA from cytosol to the nucleus may be improved by using the nuclear localization signal (NLS) found in some nuclear proteins. If the vector contains one or several NLS, either as covalently or non-covalently DNA-linked peptides, a competition may take place between the rate of dissociation of the DNA-vector complexes and the rate of loading of the complexes to the NLS-mediated nucleus importation machinery. This equilibrium may be displaced towards the importation pathway by the use of NLS-bearing proteins instead of peptides. The possibility of recruiting normal endogenous cellular pathways of nuclear uptake to promote entry of exogenously applied DNA through the nuclear pore complex would, thus, seem promising. Nevertheless, attempts to improve the transport of DNA to the nucleus through the use of NLSs have achieved limited success. Although these systems show improved transgene expression, little is known about how they function in transfected cells, and the optimal formulation for gene expression is yet to be determined.     

Phosphonium-containing polyelectrolytes for nonviral gene delivery

Nonviral gene therapy focuses intensely on nitrogen-containing macromolecules and lipids to condense and deliver DNA as a therapeutic for genetic human diseases. For the first time, DNA binding and gene transfection experiments compared phosphonium-containing macromolecules with their respective ammonium analogs. Conventional free radical polymerization of quaternized 4-vinylbenzyl chloride monomers afforded phosphonium- and ammonium-containing homopolymers for gene transfection experiments of HeLa cells. Aqueous size exclusion chromatography confirmed similar absolute molecular weights for all polyelectrolytes. DNA gel shift assays and luciferase expression assays revealed phosphonium-containing polymers bound DNA at lower charge ratios and displayed improved luciferase expression relative to the ammonium analogs. The triethyl-based vectors for both cations failed to transfect HeLa cells, whereas tributyl-based vectors successfully transfected HeLa cells similar to Superfect demonstrating the influence of the alkyl substituent lengths on the efficacy of the gene delivery vehicle. Cellular uptake of Cy5-labeled DNA highlighted successful cellular uptake of triethyl-based polyplexes, showing that intracellular mechanisms presumably prevented luciferase expression. Endocytic inhibition studies using genistein, methyl β-cyclodextrin, or amantadine demonstrated the caveolae-mediated pathway as the preferred cellular uptake mechanism for the delivery vehicles examined. Our studies demonstrated that changing the polymeric cation from ammonium to phosphonium enables an unexplored array of synthetic vectors for enhanced DNA binding and transfection that may transform the field of nonviral gene delivery.     

Can nuclear localization signals enhance nuclear localization of plasmid DNA?

Nonviral vectors are safer and more cost-effective than viral vectors but are significantly less efficient, and thus, increasing the efficiency of nonviral vectors remains an important objective. One way to overcome this problem is by stimulating the nuclear localization of exogenous genes. Nuclear localization signals (NLSs) are known to be involved in the active transport of exogenous proteins and probes into the nucleus. However, stimulation of nuclear localization of plasmid DNA has yet to be confirmed completely. In the present study, we prepared plasmid DNA-NLS peptide conjugates and adjusted spacer length and number introduced in an attempt to increase transfection efficiency. In comparison to conjugates with unmodified plasmid DNA and short spacers, we found that NLS-plasmid DNA conjugates with covalent bonding by diazo coupling through PEG chain (MW 3400) stimulated complexation with the nuclear transport proteins importin alpha and importin beta. Evaluation of transfection showed higher expression efficiency with plasmid DNA-NLS peptide conjugates than with unmodified plasmids. However, evaluation of intracellular trafficking after microinjection into the cytoplasm showed plasmid DNA-NLS peptide conjugates only within the cytoplasm; there was no NLS-plasmid stimulation of nuclear localization. Our findings suggest that stimulation of plasmid nuclear localization cannot be achieved merely by changing spacer length or chemically modifying plasmid DNA-NLS peptide conjugates. An additional mechanism must be involved.     

Characterization of Ku70(2)-NLS as bipartite nuclear localization sequence for non-viral gene delivery

Several barriers have to be overcome in order to achieve gene expression in target cells, e.g. cellular uptake, endosomal release and translocation to the nucleus. Nuclear localization sequences (NLS) enhance gene delivery by increasing the uptake of plasmid DNA (pDNA) to the nucleus. So far, only monopartite NLS were analysed for non-viral gene delivery. In this study, we examined the characteristics of a novel bipartite NLS like construct, namely NLS Ku70. We synthesized a dimeric structure of a modified NLS from the Ku70 protein (Ku70(2)-NLS), a nuclear transport active mutant of Ku70(2)-NLS (s1Ku70(2)-NLS) and a nuclear transport deficient mutant of Ku70(2)-NLS (s2Ku70(2)). We examined the transfection efficiency of binary Ku70(2)-NLS/DNA and ternary Ku70(2)-NLS/PEI/DNA gene vector complexes in vitro by using standard transfection protocols as well as the magnetofection method. The application of Ku70(2)-NLS and s1Ku70(2)-NLS increased gene transfer efficiency in vitro and in vivo. This study shows for the first time that the use of bipartite NLS compounds alone or in combination with cationic polymers is a promising strategy to enhance the efficiency of non-viral gene transfer.     

Characterization of the nuclear localization signal of the mouse TET3 protein

DNA demethylation is associated with gene activation and is mediated by a family of ten-eleven translocation (TET) dioxygenase. The TET3 protein is a 1668-amino-acid DNA demethylase that is predicted to possess five nuclear localization signals (NLSs). In this paper, we used a series of green fluorescent protein-tagged and mutation constructs to identify a conserved NLS (KKRK) embedded between amino acid 1615 and 1618 of mouse TET3. The KKRK sequence facilitates the cytoplasmic protein’s translocation into the nucleus. Additionally TET3 may be imported into the nucleus by importin-α and importin-β.     

Nuclear-targeted minicircle to enhance gene transfer with non-viral vectors in vitro and in vivo

BACKGROUND: To develop more efficient non-viral vectors, we have previously described a novel approach to attach a nuclear localisation signal (NLS) to plasmid DNA, by generating a fusion protein between the tetracycline repressor protein TetR and an SV40 NLS peptide (TetR-NLS). The high affinity of TetR for the DNA sequence tetO is used to bind the NLS to DNA. We have now investigated the ability of this system displaying the SV40 NLS or HIV-1 TAT peptide to enhance nuclear import of a minimised DNA construct more suitable for in vivo gene delivery: a minicircle. METHODS: We have produced a new LacZ minicircle compatible with the TetR system. After transfection of the minicircle in combination with TetR-NLS or TetR-TAT using different transfection agents, we first measured beta-galactosidase activity in vitro. We then used a special delivery technique, in which DOTAP/cholesterol liposomes and DNA/protein complexes are sequentially injected intravenously, to evaluate the activity of this system in vivo. RESULTS: In vitro results showed a 30-fold increase in transfection efficiency of the nuclear-targeted minicircle compared to normal plasmid lipofection. Results on cell cycle arrested cells seem to indicate a different mechanism between the TetR-NLS and TetR-TAT. Finally, we demonstrate a more than 6-fold increase in beta-galactosidase expression in the mouse lung using the minicircle and the TetR-TAT protein. This increase is specific for the peptide sequence and is not observed with the control protein TetR. CONCLUSIONS: Our results indicate that the combination of a minicircle DNA construct with a TetR nuclear-targeting system is able to potentiate gene expression of non-viral vectors.     

Nuclear localization signals of the BRCA2 protein

BRCA2 is a tumor suppressor gene whose germline mutations increase the lifetime risk of breast cancer. BRCA2 encodes a large nuclear protein involved in DNA repair, but the location of its functional domain has been unclear. Here, we report nuclear localization signals (NLSs) of the BRCA2 protein. By expressing various portions of the BRCA2 protein tagged with enhanced green fluorescent protein in HeLa cells, we show that the C-terminal domain is necessary for nuclear localization. Two regions in the C-terminal domain were identified with functional NLSs by site-directed mutagenesis analyses. The NLSs locate between the germline mutation found in the most downstream position and the polymorphic stop codon, suggesting that defects in the proper nuclear transport of the BRCA2 protein are causative of carcinogenesis. Our data thus provide a possible explanation for the high frequency of frame-shift and nonsense mutations in BRCA2 of hereditary breast cancer patients.     

HIV-1 TAT-mediated protein transduction and subcellular localization using novel expression vectors

Several novel prokaryotic and eukaryotic expression vectors were constructed for protein transduction and subcellular localization. These vectors employed an N-terminal stretch of 11 basic amino acid residues (47-57) from the human immunodeficiency virus type 1 (HIV-1) TAT protein transduction domain (PTD) for protein translocation and cellular localization. The vectors also contained a six-histidine (His(6)) tag at the N- or C-terminus for convenient purification and detection, and a multiple cloning site for easy insertion of foreign genes. Some heterologous genes including HSV-TK, Bcl-rambo, Smac/DIABLO and GFP were fused in-frame to TAT PTD and successfully overexpressed in Escherichia coli. The purified TAT-GFP fusion protein was able to transduce into the mammalian cells and was found to locate mainly in the cytosol when exogenously added to the cell culture medium. However, using a transfection system, mammalian-expressed TAT-GFP predominantly displayed a nuclear localization and nucleolar accumulation in mammalian cell lines. This discrepancy implies that the exact subcellular localization of transduced protein may depend on cell type, the nature of imported proteins and delivery approach. Taken together, our results demonstrate that a TAT PTD length of 11 amino acids was sufficient to confer protein internalization and its subsequent cellular localization. These novel properties allow these vectors to be useful for studying protein transduction and nuclear import.     

Human-derived NLS enhance the gene transfer efficiency of chitosan

Nuclear import is considered as one of the major limitations for non-viral gene delivery systems and the incorporation of nuclear localization signals (NLS) that mediate nuclear intake can be used as a strategy to enhance internalization of exogenous DNA.In this work, human-derived endogenous NLS peptides based on insulin growth factor binding proteins (IGFBP), namely IGFBP-3 and IGFBP-5, were tested for their ability to improve nuclear translocation of genetic material by non-viral vectors. Several strategies were tested to determine their effect on chitosan mediated transfection efficiency: co-administration with polyplexes, co-complexation at the time of polyplex formation, and covalent ligation to chitosan. Our results show that co-complexation and covalent ligation of the NLS peptide derived from IGFBP-3 to chitosan polyplexes yields a 2-fold increase in transfection efficiency, which was not observed for NLS peptide derived from IGFBP-5.These results indicate that the integration of IGFBP-NLS-3 peptides into polyplexes has potential as a strategy to enhance the efficiency of non-viral vectors.     

Nuclear localization signal peptide enhances transfection efficiency and decreases cytotoxicity of poly(agmatine/N,N′-cystamine-bis-acrylamide)/pDNA complexes

At present, nonviral gene vectors develop rapidly, especially cationic polymers. A series of bioreducible poly(amide amine) (PAA) polymers containing guanidino groups have been synthesized by our research team. These novel polymer vectors demonstrated significantly higher transfection efficiency and lower cytotoxicity than polyethylenimine (PEI)—25kDa. However, compared with viral gene vectors, relatively low transfection efficiency, and high cytotoxicity are still critical problems confronting these polymers. In this study, poly(agmatine/N,N′-cystamine-bis-acrylamide) p(AGM-CBA) was selected as a model polymer, nuclear localization signal (NLS) peptide PV7 (PKKKRKV) with good biocompatibility and nuclear localization effect was introduced to investigate its impact on transfection efficiency and cytotoxicity. NLS peptide-mediated in vitro transfection was performed in NIH 3T3 cells by directly incorporating NLS peptide with the complexes of p(AGM-CBA)/pDNA. Meanwhile, the transfection efficiency and cytotoxicity of these complexes were evaluated. The results showed that the transfection efficiency could be increased by 5.7 times under the appropriate proportion, and the cytotoxicity brought by the polymer vector could be significantly reduced.     

核定位信号肽用于基因转移的研究进展

核定位信号(nuclear localization signal,NLS)是一段富含Arg、Lys的氨基酸序列,它存在于真核细胞核蛋白和病毒蛋白中,并具有引导它们趋向定位核区的功能。近年来发展的利用含核定位信号肽的非病毒载体为基因转移提供了一个崭新的途径。     

Factors influencing the ability of nuclear localization sequence peptides to enhance nonviral gene delivery

Nonviral gene delivery is limited by inefficient transfer of DNA from the cytoplasm to the nucleus. Nuclear localization sequence (NLS) peptides have been widely used to exploit intracellular transport mechanisms and promote nuclear uptake of DNA. However, the exact conditions to successfully utilize the properties of NLS peptides are still unclear. In the present study a panel of NLS peptides that bind different transport receptors were compared for their ability to enhance nonviral gene transfer. Several factors such as method of incorporating the NLS peptide, type of NLS peptide, DNA morphology, and proper characterization of NLS peptide/DNA conjugates were identified as important considerations in utilizing NLS peptides to enhance gene transfer. In particular, it was shown that a peptide derived from human T cell leukaemia virus type 1 (HTLV) was able to effectively condense DNA into discrete particles and mediate levels of transgene expression up to 32-fold greater than polylysine-based polyplexes. This is the first study to demonstrate efficient transfection mediated by an importin beta-binding peptide based on the HTLV sequence. Promising results were also achieved with a 7-fold increase in gene expression using a NLS peptide/DNA conjugate formed by site-specific linkage of an extended SV40 peptide via a peptide nucleic acid (PNA) clamp. Altogether, the results from this study should help to define the requirements for successful NLS-enhanced transfection.