Poly (beta-amino ester) as an in vivo nanocarrier for therapeutic nucleic acids

Therapeutic nucleic acids are an emerging class of therapy for treating various diseases through immunomodulation, protein replacement, gene editing, and genetic engineering. However, they need a vector to effectively and safely reach the target cells. Most gene and cell therapies rely on ex vivo gene delivery, which is laborious, time-consuming, and costly; therefore, devising a systematic vector for effective and safe in vivo delivery of therapeutic nucleic acids is required to target the cells of interest in an efficient manner. Synthetic nanoparticle vector poly beta amino ester (PBAE), a class of degradable polymer, is a promising candidate for in vivo gene delivery. PBAE is considered the most potent in vivo vector due to its excellent transfection performance and biodegradability. PBAE nanoparticles showed tunable charge density, diverse structural characteristics, excellent encapsulation capacity, high stability, stimuli-responsive release, site-specific delivery, potent binding to nucleic acids, flexible binding ability to various conjugates, and effective endosomal escape. These unique properties of PBAE are an essential contribution to in vivo gene delivery. The current review discusses each of the components used for PBAE synthesis and the impact of various environmental and physicochemical factors of the body on PBAE nanocarrier.     

Exploring membrane permeability of Tomatidine to enhance lipid mediated nucleic acid transfections

Intracellular delivery of nucleic acids is one of the critical steps in the transfections. Prior findings demonstrated various strategies including membrane fusion, endosomal escape for the efficient cytoplasmic delivery. In our continuing efforts to improve the nucleic acids transfections, we harnessed cell permeable properties of Tomatidine (T), a steroidal alkaloid abundantly found in green tomatoes for maximizing intracellular delivery of lipoplexes. We doped Tomatidine into liposomes of cationic lipid with amide linker (A) from our lipid library. Six liposomal formulations (AT) of Lipid A (1?mM) with varying concentrations of Tomatidine (0–1?mM) were prepared and evaluated for their transfection efficacies. Owing to its signature characteristic of cell membrane permeability, Tomatidine modulated endocytosis process, enhanced the intracellular delivery of the lipoplexes, and in turn increased the transfection efficacy of cationic liposomes. Our findings provide ‘proof of concept’ for enhancing transfections in gene delivery applications with Tomatidine in cationic liposomal formulations. These findings can be further applied in lipid mediated gene therapy and drug delivery applications.     

分枝PEI 修饰的PLGA 纳米粒转染DNA 的研究*

目的:建立基于聚(乳酸-羟基乙酸)纳米粒(PLGA)载DNA的基因转染体系,比较用空白聚(乳酸-羟基乙酸)纳米粒(PLG-A-E)吸附质粒DNA和用分枝PEI修饰后的PLGA纳米粒(PLGA-BPEI)吸附质粒DNA优缺点。方法:用乳化蒸发法制备纳米粒,对纳米粒进行表征研究,包括包封率、Zeta电位、粒径大小、稳定性,用荧光显微镜观察它们对NIH3T3和HEK293细胞的转染效率,用MTT检测对它们细胞的毒性。结果:制备了两种基于PLGA的纳米粒,PLGA-E和PLGA-BPEI粒径大小为200-270nm,zeta电位为0-30mV,在血清和不同的pH值时两者均较稳定,转染效率PLGA-BPEI较PLGA-E高,且释放时间早,但前者较后者对细胞毒性大。结论:这两种基于PLGA纳米粒均能有效转染质粒DNA,它们存在不同的优缺点,应根据不同需要进行选择。     

Generation of magnetic nonviral gene transfer agents and magnetofection in vitro

This protocol details how to design and conduct experiments to deliver nucleic acids to adherent and suspension cell cultures in vitro by magnetic force-assisted transfection using self-assembled complexes of nucleic acids and cationic lipids or polymers (nonviral gene vectors), which are associated with magnetic (nano) particles. These magnetic complexes are sedimented onto the surface of the cells to be transfected within minutes by the application of a magnetic gradient field. As the diffusion barrier to nucleic acid delivery is overcome, the full vector dose is targeted to the cell surface and transfection is synchronized. In this manner, the transfection process is accelerated and transfection efficiencies can be improved up to several 1,000-fold compared with transfections carried out with nonmagnetic gene vectors. This protocol describes how to accomplish the following stages: synthesis of magnetic nanoparticles for magnetofection; testing the association of DNA with the magnetic components of the transfection complex; preparation of magnetic lipoplexes and polyplexes; magnetofection; and data processing. The synthesis and characterization of magnetic nanoparticles can be accomplished within 3-5 d. Cell culture and transfection is then estimated to take 3 d. Transfected gene expression analysis, cell viability assays and calibration will probably take a few hours. This protocol can be used for cells that are difficult to transfect, such as primary cells, and may also be applied to viral nucleic acid delivery. With only minor alterations, this protocol can also be useful for magnetic cell labeling for cell tracking studies and, as it is, will be useful for screening vector compositions and novel magnetic nanoparticle preparations for optimized transfection efficiency in any cell type.     

Mixtures of poly(triethylenetetramine/cystamine bisacrylamide) and poly(triethylenetetramine/cystamine bisacrylamide)-g-poly(ethylene glycol) for improved gene delivery

Branched disulfide-containing poly(amido ethyleneimines) (SS-PAEIs) are biodegradable polymeric gene carrier analogues of the well-studied, nondegradable, and often toxic branched polyethylenimines (bPEIs), but with distinct advantages for cellular transgene delivery. Clinical success of polycationic gene carriers is hampered by obscure design and formulation requirements. This present work reports synthetic and formulation properties for a graft copolymer of poly(ethylene glycol) (PEG) and a branched SS-PAEI, poly(triethylentetramine/cystaminebisacrylamide) (p(TETA/CBA)). Several laboratories have previously demonstrated the advantages of PEG conjugation to gene carriers, but have also shown that PEG conjugation may perturb plasmid DNA (pDNA) condensation, thereby interfering with nanoparticle formation. With this foundation, our studies sought to mix various amounts of p(TETA/CBA) and p(TETA/CBA)-g-PEG2k to alter the relative amount of PEG in each formulation used for polyplex formation. The influence of different PEG/polycation amounts in the formulations on polymer/nucleic acid nanoparticle (polyplex) size, surface charge, morphology, serum stability and transgene delivery was studied. Polyplex formulations were prepared using p(TETA/CBA)-g-PEG2k, p(TETA/CBA), and mixtures of the two species at 10/90 and 50/50 volumetric mixture ratios (wt/wt %), respectively. As expected, increasing the amount of PEG in the formulation adversely affects polyplex formation. However, optimal polymer mixtures could be identified using this facile approach to further clarify design and formulation requirements necessary to understand and optimize carrier stability and biological activity. This work demonstrates the feasibility to easily overcome typical problems observed when polycations are modified and thus avoids the need to synthesize multiple copolymers to identify optimal gene carrier candidates. This approach may be applied to other polycation-PEG preparations to alter polyplex characteristics for optimal stability and biological activity.     

Effects of base polymer hydrophobicity and end-group modification on polymeric gene delivery

A new 320-member polymer library of end-modified poly(β-amino ester)s was synthesized. This library was chosen such that small differences to the structures of component backbone, side-chain, and end-group monomers could be systematically and simultaneously evaluated. The in vitro transfection efficacy and cytotoxicity of DNA nanoparticles formed from this library were assessed. This library approach not only enabled us to synthesize and test a large variety of structures rapidly but also provided us with a robust data set to analyze for the effect of small structural permutations to polymer chain structure. Small changes to the side chains, backbones, and end groups within this polymer library produced dramatic results, with transfection efficacy of CMV-Luc varying over 4 orders in a 96-well plate format. Increasing hydrophobicity of the base polymer backbone and side chain tended to increase transfection efficacy, but the most hydrophobic side chains and backbones showed the least requirement for a hydrophobic pair. Optimal PBAE formulations were superior to commercially available nonviral alternatives FuGENE HD and Lipofectamine 2000, enabling ~3-fold increased luminescence (2.2 × 10(6) RLU/well vs 8.1 × 10(5) RLU/well) and 2-fold increased transfection percentage (76.7% vs 42.9%) as measured by flow cytometry with comparable or reduced toxicity.     

Addition of "charge-shifting" side chains to linear poly(ethyleneimine) enhances cell transfection efficiency

We reported recently that the addition of ester-functionalized, "charge-shifting" side chains to linear poly(ethyleneimine) (LPEI) can be used to design polyamines that promote both self-assembly and self-disassembly with DNA in aqueous environments. This investigation sought to characterize the influence of charge-shifting side chains on the ability of LPEI to mediate cell transfection and understand the extent to which increases (or decreases) in levels of transfection could be understood in terms of time-dependent changes in the net charges of these polymers. We report that the addition of "charge-shifting" side chains to LPEI leads to significant increases in levels of LPEI-mediated transfection. In particular, polymer 1e, functionalized with 20 mol % ester-functionalized side chains, mediates levels of transgene expression in vitro up to 8-fold higher than LPEI. Experiments using an amide-functionalized analog of polymer 1e demonstrated that the esters in polymer 1e play an important role in promoting increased levels of transfection. These results, in combination with the results of additional gel electrophoresis experiments, provide support for the view that increases in transfection result from time-dependent changes in the net charge of polymer 1e and the disruption of ionic interactions in polyplexes. Additional support for this view is provided by the results of confocal microscopy experiments and measurements of fluorescence resonance energy transfer, which suggest that polymer 1e promotes the disruption of polyplexes in intracellular environments effectively. The approach reported here provides a means of addressing one important "late-stage" obstacle to polyplex-mediated transfection (polyplex unpackaging). If integrated successfully with methods that have been developed to address other important barriers to transfection, this general approach could lead to the development of multifunctional polyplexes that mimic more effectively the range of functions of viruses as agents for the delivery of DNA.     

Transferrin-containing, cyclodextrin polymer-based particles for tumor-targeted gene delivery

Transferrin is a well-studied ligand for tumor targeting due to upregulation of transferrin receptors in numerous cancer cell types. Here, we report the development of a transferrin-modified, cyclodextrin polymer-based gene delivery system. The delivery system is comprised of a nanoparticle (formed by condensation of a cyclodextrin polycation with nucleic acid) that is surface-modified to display poly(ethylene glycol) (PEG) for increasing stability in biological fluids and transferrin for targeting of cancer cells that express transferrin receptor. A transferrin-PEG-adamantane conjugate is synthesized for nanoparticle modification. The transferrin conjugate retains high receptor binding and self-assembles with the nanoparticles by adamantane (host) and particle surface cyclodextrin (guest) inclusion complex formation. At low transferrin modification, the particles remain stable in physiologic salt concentrations and transfect K562 leukemia cells with increased efficiency over untargeted particles. The increase in transfection is eliminated when transfections are conducted in the presence of excess free transferrin. The transferrin-modified nanoparticles are appropriate for use in the systemic delivery of nucleic acid therapeutics for metastatic cancer applications.     

A simplified polyethylenimine-mediated transfection process for large-scale and high-throughput applications

Transient gene expression in mammalian cells is a valuable alternative to stable cell lines for the rapid production of large amounts of recombinant proteins. While the establishment of stable cell lines takes 2-6 months, milligram amounts of protein can be obtained within a week following transfection. The polycation polyethylenimine (PEI) is one of the most utilized reagents for small- to large-scale transfections as it is simple to use and, when combined with optimized expression vectors and cell lines, provides high transfection efficiency and titers. As with most transfection reagents, PEI-mediated transfection involves the formation of nanoparticles (polyplexes) which are obtained by its mixing with plasmid DNA. A short incubation period that allows polyplexes to reach their optimal size is performed prior to their addition to the culture. As the quality of polyplexes directly impacts transfection efficiency and productivity, their formation complicates scalability and automation of the process, especially when performed in large-scale bioreactors or small-scale high-throughput formats. To avoid variations in transfection efficiency and productivity that arise from polyplexes formation step, we have optimized the conditions for their creation directly in the culture by the consecutive addition of DNA and PEI. This simplified approach is directly transferable from suspension cultures grown in 6-well plates to shaker flasks and 5-L WAVE bioreactors. As it minimizes the number of steps and does not require an incubation period for polyplex formation, it is also suitable for automation using static cultures in 96-well plates. This "direct" transfection method thus provides a robust platform for both high-throughput expression and large-scale production of recombinant proteins.     

Stimuli-responsive nanocarriers for intracellular delivery

The emergence of different nanoparticles (NPs) has made a significant revolution in the field of medicine. Different NPs in the form of metallic NPs, dendrimers, polymeric NPs, carbon quantum dots and liposomes have been functionalized and used as platforms for intracellular delivery of biomolecules, drugs, imaging agents and nucleic acids. These NPs are designed to improve the pharmacokinetic properties of the drug, improve their bioavailability and successfully surpass physiological or pathological obstacles in the biological system so that therapeutic efficacy is achieved. In this review I present some of the current approaches used in intracellular delivery systems, with a focus on various stimuli-responsive nanocarriers, including cell-penetrating peptides, to highlight their various biomedical applications.     

Effects of structure of beta-cyclodextrin-containing polymers on gene delivery

Linear cationic beta-cyclodextrin-based polymers (betaCDPs) are capable of forming polyplexes with nucleic acids and transfecting cultured cells. The betaCDPs are synthesized by the condensation of a diamino-cyclodextrin monomer A with a diimidate comonomer B. In this paper, the effects of polymer structure on polyplex formation, in vitro transfection efficiency and toxicity are elucidated. By comparison of the betaCDPs to polyamidines lacking cyclodextrins, the inclusion of a cyclodextrin moiety in the comonomer A units reduces the IC50s of the polymer by up to 3 orders of magnitude. The spacing between the cationic amidine groups is also important. Different polymers with 4, 5, 6, 7, 8, and 10 methylene units (betaCDP4, 5, 6, 7, 8, and 10) in the comonomer B molecule are synthesized. Transfection efficiency is dependent on comonomer B length with up to 20-fold difference between polymers. Optimum transfection is achieved with the betaCDP6 polymer. In vitro toxicity varied by 1 order of magnitude and the lowest toxicity is observed with betaCDP8. The LD40 of the betaCDP6 to mice is 200 mg/kg, making this polymer a promising agent for in vivo gene delivery applications.     

Cost-effective gene transfection by DNA compaction at pH 4.0 using acidified,long shelf-life polyethylenimine

Introduction of genetic material into cells is an essential prerequisite for current research in molecular cell biology. Although transfection with commercially available reagents results in excellent gene expression, their high costs are obstacles to experimentation with a large number or large scales of transfection. The cationic polymer linear-polyethylenimine (MW 25,000) (PEI), one of the most cost-effective vehicles, facilitates DNA compaction by polyplex formation, which leads to efficient delivery of DNA into cells by endocytosis. However, the use of PEI is still limited because of substantial cytotoxicity and intolerable deterioration in transfection efficiency by its low stability. Here, we show that acidification of PEI is important for its transfection activity. Dissolving PEI powder in 0.2N HCl confers a long shelf-life for PEI storage at 4 and −80 °C, and the polyplex formation of plasmid DNA with PEI is optimized in lactate-buffered saline at pH 4.0. Furthermore, changing the culture medium at 8–12 h posttransfection can minimize the cytotoxicity of PEI without sacrificing the high transfection efficiency comparable to that of commercial reagents. The cost per test using acidified PEI is drastically reduced to approximately 1:10,000, compared with commercial reagents. Thus, we conclude that acidification of PEI satisfactorily accomplishes cost-effective, high-efficiency transfection.     

Enhancement of DNA uptake in FUT8‐deleted CHO cells for transient production of afucosylated antibodies

Removal of the core α1,6 fucose from the glycans in the Fc region of IgG1 antibodies has been demonstrated to improve antibody‐dependent cellular cytotoxicity (ADCC) activity. In order to produce afucosylated antibodies using transient transfection, a FUT8 knockout (FUT8KO) cell line was generated in a CHO host cell line using the zinc finger nuclease technology. Transient transfection of DNA into mammalian cells using the cationic polymer, polyethylenimine (PEI), is commonly used for rapid generation of recombinant proteins. FUT8KO cells evaluated in PEI transfections yielded lower titers than parental CHO WT cells. FACS and HPLC analyses revealed that the FUT8KO cells had lower cell surface heparan sulfate (HS) levels than CHO WT. Removal of cell surface HS resulted in reduced uptake of PEI‐transfected DNA (PEI:DNA) and lower transfection titers suggesting that PEI:DNA relies on HS for binding and cellular entry. The absence of cell surface HS did not severely impact transfections performed with cationic liposomes. We undertook two approaches to improve transient production of afucosylated antibodies. First, we evaluated transfection of FUT8KO cells with cationic liposomes, which were observed to be less dependent on HS levels for uptake. Transfection of FUT8KO cells using the cationic liposome, DMRIE‐C, produced similar titers to CHO WT in both shake flask and large‐scale 10 L bioreactors. The second approach was to engineer a cell line overexpressing exostosin‐1 (EXT1), an enzyme responsible for HS chain elongation, to increase HS content. EXT1‐FUT8KO and CHO WT cells produced comparable levels of antibody from PEI transfections. Biotechnol. Bioeng. 2010;106: 751–763. © 2010 Wiley Periodicals, Inc.     

Synthesis and characterization of a novel arginine-grafted dendritic block copolymer for gene delivery and study of its cellular uptake pathway leading to transfection

We synthesized a novel arginine-grafted dendritic block copolymer, R-PAMAM-PEG-PAMAM-R G5 (PPP5-R) for gene delivery systems. Its Mw was measured as 2.74 x 104 Da by MALDI-TOF, and approximately 36 arginine residues are found to be grafted to the polymer by 1H NMR. PPP5-R was able to form polyplexes with plasmid DNA, the average size of which was about 200 nm. Positive zeta-potential values (+22 to +28 mV) of PPP5-R polyplex indicate the formation of positively charged stable polyplex particles and suggest that large dendritic blocks with high positive charge may not be fully shielded by PEG chains even after PEG-coated complex formation. PPP5-R polyplex shows enhanced water solubility due to the polymer's PEG core and also shows low cytotoxicity, representing the potential for in vivo application. We identified the greatly enhanced transfection efficiency of PPP5-R in comparison with that of native PPP5 on various cell lines. Moreover, in view of the result of various cellular uptake inhibitor treatments during a transfection step, the cellular uptake of PPP5-R polyplex leading to effective transfection is thought to be not dependent on one exclusive pathway and to have the possibility of multiple pathways (caveolae-, clathrin-, and macropinocytosis-mediated pathways), contrary to the caveolae-dependent uptake of the PPP5 polyplex lacking arginine residues.     

Localized transfection with magnetic beads coated with PCR products and other nucleic acids

The bead transfection method involves binding nucleic acids onto 3-microm-diameter paramagnetic beads, treating the beads with transfection reagent, and using them as scaffolds to direct transfection to individual cells or regions in a population. Typically, PCR products are used because they can be conveniently generated using biotinylated primers and can introduce site-directed mutations, without the need for cloning or plasmid purification. However, the method can be adapted to transfect plasmid DNA or RNA. The magnetic properties of the beads allows magnets to direct the loci of transfection in cell culture; magnetic arrays are built in cell culture chambers to allow multiple parallel transfections on the same microscope coverslip. The PCR reaction and transfection can be carried out in 1 d, and transfection results can be viewed in 24-48 h.     

Polyethyleneimine-based immunopolyplex for targeted gene transfer in human lymphoma cell lines

Background

Specific and efficient delivery of genes into targeted cells is a priority objective in non‐viral gene therapy. Polyethyleneimine‐based polyplexes have been reported to be good non‐viral transfection reagents. However, polyplex‐mediated DNA delivery occurs through a non‐specific mechanism. This article reports the construction of an immunopolyplex, a targeted non‐viral vector based on a polyplex backbone, and its application in gene transfer over human lymphoma cell lines.

Methods

Targeting elements (biotin‐labeled antibodies), which should recognize a specific element of the target cell membrane and promote nucleic acid entry into the cell, were attached to the polyplex backbone through a bridge protein (streptavidin). Immunopolyplex transfection activity was studied in several hematological cell lines [Jurkat (CD3+/CD19?), Granta 519 (CD3?/ CD19+), and J.RT3‐T3.5 (CD3?/CD19?)] using the EGFP gene as a reporter gene and anti‐CD3 and anti‐CD19 antibodies as targeting elements. Transfection activity was evaluated via green fluorescence per cell and the percentage of positive cells determined by flow cytometry.

Results

A significant selectivity of gene delivery was observed, since the anti‐CD3 immunopolyplex worked only in Jurkat cells while the anti‐CD19 immunopolyplex worked only in the Granta cell line. Moreover, transfection of a CD3+/CD3? cell mixture with anti‐CD3 immunopolyplexes showed up to 16‐fold more transfection in CD3+ than in CD3? cells. Several non‐specific transfection reagents showed poor or no transfection activity.

Conclusion

It is concluded that immunopolyplex is a good non‐viral vector for specific and selective nucleic acid delivery. Immunopolyplex design allows easy replacement of the targeting element (antibody) – the streptavidin–polyplex backbone remaining intact – thereby conferring high versatility. Copyright © 2002 John Wiley & Sons, Ltd.

     

Nanostructure of polyplexes formed between cationic diblock copolymer and antisense oligodeoxynucleotide and its influence on cell transfection efficiency

Although various cationic polymers have been used to condense anionically charged DNA to improve their transfection efficiency, there is still a lack of fundamental understanding about how to control the nanostructure and charge of the polyplexes formed and how to relate such information to cell transfection efficiency. In this work, we have synthesized a weak cationic and phosphorylcholine-containing diblock copolymer and used it as a model vector to deliver an antisense oligodeoxynucleotide (ODN) into HeLa cells. Small angle neutron scattering (SANS) was used to determine the copolymer/ODN polyplex structure. The SANS data revealed the formation of polyplex nanocylinders at high copolymer (N)/ODN (P) charge ratios, where N symbolizes the amine groups on the copolymer and P symbolizes the phosphate groups. However, the cylindrical lengths remained constant, indicating that the ODN binding over this region did not alter the cylindrical shape of the copolymer in solution. As the N/P ratio decreased and became close to unity the polyplex diameters remained constant, but their lengths increased substantially, suggesting the end-to-end bridging by ODN binding between copolymer cylinders. As the N/P ratios went below unity (with ODN in excess), the polyplex diameters increased substantially, indicating different ODN bridging to bundle the small polyplexes together. Transfection studies from HeLa cells indicated a steady increase in transfection efficiency with increasing cationic charge and decreasing polyplex size. Cell growth inhibition assay showed significant growth inhibition by the polyplexes coupled with weak cytotoxicity, indicating effective ODN delivery. While this study has confirmed the overall charge effect, it has also revealed progressive structural changes of the polyplexes against varying charge ratio, thereby providing useful insight into the mechanistic process behind the ODN delivery.     

Efficient nucleic acid transduction with lipoplexes containing novel piperazine- and polyamine-conjugated cholesterol derivatives

To advance the use of cationic lipids for non-viral nucleic acid vector formulation, a panel of novel nitrogen heterocycle cholesteryl derivatives containing a biodegradable carbamate linker was synthesised. Optimally acting piperazine and cyclen compounds had nucleic acid-binding and lipoplex nanoparticle formation properties that were suitable for their use as non-viral vectors. It was found that the lipoplexes formed were capable of efficient non-toxic nucleic acid delivery to cells in culture. The chemical structure of individual cationic lipids, which is likely to influence lipoplex formation, affected efficiency of DNA or RNA transfection. The results indicated that the cyclen containing compound possessing two cholesteryl moieties resulted in efficient siRNA-mediated target gene silencing but was a poor reagent for DNA transfection.     

Poly(beta-amino ester) and cationic phospholipid-based lipopolyplexes for gene delivery and transfection in human aortic endothelial and smooth muscle cells

Safe and effective nonviral gene delivery and transfection in primary human vascular endothelial cells (EC) and smooth muscle cells (SMC) has tremendous potential for cardiovascular diseases such as in the treatment of coronary restenosis. Using a combination of a cationic biodegradable polymer, poly(beta-amino ester) (PBAE), and a cationic phospholipid, 1,2-dioleoyl-3-trimethylammonium propane (DOTAP), we have engineered a lipopolyplex nanovector system that can transfect EC and SMC cells with reasonably high efficiency. For instance, upon addition of 1.0 microg DNA complexed in lipopolyplexes the transfection efficiency in SMC was 20% and in EC was 33%. The results of this study shows that PBAE-DOTAP-plasmid DNA lipopolyplexes are a promising nonviral vector system for gene delivery and transfection in EC and SMC.     

pH-sensitive cationic polymer gene delivery vehicle: N-Ac-poly(L-histidine)-graft-poly(L-lysine) comb shaped polymer

Advancing biotechnology spurs the development of new pharmaceutically engineered gene delivery vehicles. Poly(L-histidine) ?PLH? has been shown to induce membrane fusion at endosomal pH values, whereas PLL has a well documented efficacy in polyplex formation. Therefore, N-Ac-poly(L-histidine)-graft-poly(L-lysine) ?PLH-g-PLL? was synthesized by grafting poly(L-histidine) to poly(L-lysine) ?PLL?. PLH-g-PLL formed polyplex particles by electrostatic interactions with plasmid DNA ?pDNA?. The mean particle size of the polyplexes was in the range of 117 +/- 6 nm to 306 +/- 77 nm. PLH-g-PLL gene carrier demonstrated higher transfection efficacy in 293T cells than PLL at all equivalent weight ratios with pDNA. The inclusion of chloroquine as an endosomolytic agent enhanced transfection for both PLL and PLH-g-PLL gene carriers. PLH-g-PLL enhanced beta-galactosidase expression compared to PLL, but still increased in efficacy when chloroquine was included.