Chloride accumulation and swelling in endosomes enhances DNA transfer by polyamine-DNA polyplexes

The "proton sponge hypothesis" postulates enhanced transgene delivery by cationic polymer-DNA complexes (polyplexes) containing H+ buffering polyamines by enhanced endosomal Cl- accumulation and osmotic swelling/lysis. To test this hypothesis, we measured endosomal Cl- concentration, pH, and volume after internalization of polyplexes composed of plasmid DNA and polylysine (POL), a non-buffering polyamine, or the strongly buffering polyamines polyethylenimine (PEI) or polyamidoamine (PAM). [Cl-] and pH were measured by ratio imaging of fluorescently labeled polyplexes containing Cl- or pH indicators. [Cl-] increased from 41 to 80 mM over 60 min in endosomes-contained POL-polyplexes, whereas pH decreased from 6.8 to 5.3. Endosomal Cl- accumulation was enhanced (115 mM at 60 min) and acidification was slowed (pH 5.9 at 60 min) for PEI and PAM-polyplexes. Relative endosome volume increased 20% over 75 min for POL-polyplexes versus 140% for PEI-polyplexes. Endosome lysis was seen at >45 min for PEI but not POL-containing endosomes, and PEI-containing endosomes showed increased osmotic fragility in vitro. The slowed endosomal acidification and enhanced Cl- accumulation and swelling/lysis were accounted for by the greater H+ buffering capacity of endosomes containing PEI or PAM versus POL (>90 mM versus 46 H+/pH unit). Our results provide direct support for the proton sponge hypothesis and thus a rational basis for the design of improved non-viral vectors for gene delivery.     

Measuring the pH environment of DNA delivered using nonviral vectors: implications for lysosomal trafficking

The degradation of DNA in lysosomes represents a major obstacle to efficient nonviral gene delivery. The rational design of vectors that overcome this obstacle requires a better understanding of the lysosomal barrier to gene delivery, which in turn requires a means to investigate this intermediate step. To this end, we developed a technique to measure the pH environment of delivered DNA, from which the degree to which vectors avoided trafficking to acidic Iysosomes could be determined. The measured average pH of DNA delivered using poly-L-lysine (PLL) polyplexes was 4.5, suggesting that PLL polyplexes were trafficked to acidic lysosomes. Other vectors could avoid or buffer the pH of Iysosomes as DNA delivered using Lipofectamine Plus, polyethylenimine (PEI), linear polyethylenimine (LPEI), and two degradable poly(beta-amino ester)s (poly-1 and poly-2) had average pH values of 7.1, 5.9, 5.0, 6.7, and 6.4, respectively.     

Potocytosis and cellular exit of complexes as cellular pathways for gene delivery by polycations

BACKGROUND: Although polycations are among the most efficient nonviral vectors for gene transfer, the gene expression they allow is still too low for in vivo applications. To engineer more potent polycationic vectors, the factors governing the intracellular trafficking of a plasmid complexed with current polycations need to be identified. METHODS AND RESULTS: The trafficking of plasmid DNA complexed to glycosylated polylysines or polyethylenimine (PEI) derivatives was studied by electron microscopy of human airway epithelial cells. The cellular processing of complexes varied with their size and the polycation derivative used: large complexes (> 200 nm) made with all polycationic vectors studied were internalized by macropinocytosis. In contrast, intermediate (100-200 nm) ligand-coupled polylysine and PEI complexes primarily entered through clathrin-coated pits. Complexes were then found in endosomal vesicles, accumulated in lysosomes or vesicles near the nucleus and their nuclear entry was limited. For the population of small complexes (< or = 100 nm) obtained with PEI derivatives, they were internalized through caveolae and pursued a traffic pattern of potocytosis to the endoplasmic reticulum where their fate remains unclear. Finally, some complexes exited the cells either by regurgitation when PEI derivatives were used or through an exosome-like pathway for glycosylated-polylysine complexes. CONCLUSIONS: The different pathways of complex trafficking observed in relation with complex size imply the development and study of vectors forming complexes with definite size. Moreover, the complex exit we describe may contribute to the well-established short-term efficiency of gene transfer based on synthetic vectors. It favors the engineering of vectors allowing repeated treatment.     

The role of PEI structure and size in the PEI/liposome-mediated synergism of gene transfection

Polyethylenimines (PEIs) and cationic liposomes are widely used for nonviral gene delivery. When PEIs have been used alone, the transfection efficiency has been higher for larger or linear than smaller or branched PEIs. We have reported previously that a combination of small PEIs and liposomes results in a potentiation of transfection efficiency in vitro. Here, the role of PEI size and structure in this synergism has been clarified further. Therefore, two structurally different high MW PEIs, i.e. the linear PEI22K and branched PEI25K, were studied in the SMC cells. We found that both linear PEI22K and branched PEI25K resulted in a similar synergism and comparable transfection efficiencies. However, the potentiation for larger PEIs found in the present study was weaker than that for smaller PEIs obtained in our previous studies. In conclusion, our present and previous results demonstrate that the increment of PEI/liposome-mediated gene transfection by different types of PEIs in vitro is a common attribute that is rather associated with their size than the structure. Interestingly, the effect of PEI size seems to be opposite when combined with liposome or given alone, i.e. the small PEIs are more effective when combined and less effective when alone than the larger ones.     

Disulfide cross-linked polyethylenimines (PEI) prepared via thiolation of low molecular weight PEI as highly efficient gene vectors

Ring-opening reaction of low molecular weight polyethylenimine with an Mw of 800 Da (800 Da PEI) with methylthiirane produced thiolated polyethylenimine (PEI-SHX ). The thiolation degree X, which is the average number of thiol groups on a PEI molecule, was readily adjusted by the methylthiirane/PEI ratio. Oxidation of the thiolated PEIs with DMSO afforded disulfide cross-linked PEIs (PEI-SSX ). The molecular weights of PEI-SS X were estimated by viscosity measurement to be 7100, 8000, and 8400 for X=2.6, 6.5, and 9.4, respectively. The PEI-SSX series can bind and condense plasmid DNAs effectively forming nanosized polyplexes. The size of dry polyplexes is less than 100 nm on the TEM pictures. In solution, the size of the polyplexes was measured by DLS to be about 400 nm. In vitro experiments showed that the PEI-SS X series have a lower cytotoxicity and higher gene transfection efficiency compared with the high molecular weight PEI with Mw of 25 KDa. The presence of fetal bovine serum did not decrease the transfection efficiency. The results proved the hypothesis that reductively degradable disulfide-containing PEIs could possesses simultaneously higher gene transfection efficiency and lower cytotoxicity than the nondegradable ones.     

Differential intracellular distribution of DNA complexed with polyethylenimine (PEI) and PEI-polyarginine PTD influences exogenous gene expression within live COS-7 cells

Background

Polyethylenimine (PEI) is one of the most efficient and versatile non-viral vectors available for gene delivery. Despite many advantages over viral vectors, PEI is still limited by lower transfection efficiency compared to its viral counterparts. Considerable investigation is devoted to the modification of PEI to incorporate virus-like properties to improve its efficacy, including the incorporation of the protein transduction domain (PTD) polyarginine (Arg); itself demonstrated to facilitate membrane translocation of molecular cargo. There is, however, limited understanding of the underlying mechanisms of gene delivery facilitated by both PEI and PEI-bioconjugates such as PEI-polyarginine (PEI-Arg) within live cells, which once elucidated will provide valuable insights into the development of more efficient non-viral gene delivery vectors.

Methods

PEI and PEI-Arg were investigated for their ability to facilitate DNA internalization and gene expression within live COS-7 cells, in terms of the percentage of cells transfected and the relative amount of gene expression per cell. Intracellular trafficking of vectors was investigated using fluorescent microscopy during the first 5 h post transfection. Finally, nocodazole and aphidicolin were used to investigate the role of microtubules and mitosis, respectively, and their impact on PEI and PEI-Arg mediated gene delivery and expression.

Results

PEI-Arg maintained a high cellular DNA uptake efficiency, and facilitated as much as 2-fold more DNA internalization compared to PEI alone. PEI, but not PEI-Arg, displayed microtubule-facilitated trafficking, and was found to accumulate within close proximity to the nucleus. Only PEI facilitated significant gene expression, whereas PEI-Arg conferred negligible expression. Finally, while not exclusively dependant, microtubule trafficking and, to a greater extent, mitotic events significantly contributed to PEI facilitated gene expression.

Conclusion

PEI polyplexes are trafficked by an indirect association with microtubules, following endosomal entrapment. PEI facilitated expression is significantly influenced by a mitotic event, which is increased by microtubule organization center (MTOC)-associated localization of PEI polyplexes. PEI-Arg, although enhancing DNA internalization per cell, did not improve gene expression, highlighting the importance of microtubule trafficking for PEI vectors and the impact of the Arg peptide to intracellular trafficking. This study emphasizes the importance of a holistic approach to investigate the mechanisms of novel gene delivery vectors.     

Quantifying the intracellular transport of viral and nonviral gene vectors in primary neurons

Real-time confocal particle tracking (CPT) was used to compare the transport and trafficking of polyethylenimine (PEI)/DNA nanocomplexes to that of efficient adenoviruses in live primary neurons. Surprisingly, the quantitative intracellular transport properties of PEI/DNA nonviral gene vectors are similar to that of adenoviral vectors. For example, the values of individual particle/virus transport rates and the distributions of particle/virus transport modes (i.e., the percentage undergoing active, diffusive, or subdiffusive transport) largely overlapped. In addition, both PEI/DNA vectors and adenoviruses rapidly accumulated near the cell nucleus in primary neurons despite our finding that PEI/DNA move slower in neurites than in the cell body, whereas adenoviruses move with equal rates in either location. The intracellular trafficking pathways of PEI/DNA and adenoviruses, however, were substantially different. The majority of PEI/DNA trafficked through the endolysosomal pathway so as to end up in late endosomes/lysosomes (LE/Lys), whereas adenoviruses efficiently escaped endosomes. This result suggests that the sequestration of nonviral gene vectors within acidic vesicles may be a critical barrier to gene delivery to primary neurons in the central nervous system (CNS).     

Low molecular weight polyethylenimines linked by beta-cyclodextrin for gene transfer into the nervous system

BACKGROUND: Polyethylenimines (PEIs) with high molecular weights are effective nonviral gene delivery vectors. However, the in vivo use of these PEIs can be hampered by their cellular toxicity. In the present study we developed and tested a new PEI polymer synthesized by linking less toxic, low molecular weight (MW) PEIs with a commonly used, biocompatible drug carrier, beta-cyclodextrin (CyD). METHODS AND RESULTS: The terminal CyD hydroxyl groups were activated by 1,1'-carbonyldiimidazole. Each activated CyD then linked two branched PEI molecules with MW of 600 Da to form a CyD-containing polymer with MW of 61 kDa, in which CyD served as a part of the backbone. The PEI-CyD polymer developed was soluble in water and biodegradable. In cell viability assays with sensitive neurons, the polymer performed similarly to low-MW PEIs and displayed much lower cellular cytotoxicity compared to PEI 25 kDa. The gene delivery efficiency of the polymer was comparable to, and at higher polymer/DNA ratios even higher than, that offered by PEI 25 kDa in neural cells. Attractively, intrathecal injection of plasmid DNA complexed by the polymer into the rat spinal cord provided levels of gene expression close to that offered by PEI 25 kDa. CONCLUSIONS: The polymer reported in the current study displayed improved biocompatibility over non-degradable PEI 25 kDa and mediated gene transfection in cultured neurons and in the central nervous system effectively. The new polymer would be worth exploring further as an in vivo delivery system of therapeutic genetic materials for gene therapy of neurological disorders.     

Low molecular weight polyethylenimine for efficient transfection of human hematopoietic and umbilical cord blood-derived CD34+ cells

With the emerging role of hematopoietic stem cells as potential gene and cell therapy vehicles, there is an increasing need for safe and effective nonviral gene delivery systems. Here, we report that gene transfer and transfection efficiency in human hematopoietic and cord blood CD34+ cells can be enhanced by the use of low molecular weight polyethylenimine (PEI). PEIs of various molecular weights (800-750,000) were tested, and our results showed that the uptake of plasmid DNA by hematopoietic TF-1 cells depended on the molecular weights and the N/P ratios. Treatment with PEI 2K (m.w. 2000) at an N/P ratio of 80/1 was most effective, increasing the uptake of plasmid DNA in TF-1 cells by 23-fold relative to Lipofectamine 2000. PEI 2K-enhanced transfection was similarly observed in hematopoietic K562, murine Sca-1+, and human cord blood CD34+ cells. Notably, in human CD34+ cells, a model gene transferred with PEI 2K showed 21,043- and 513-fold higher mRNA expression levels relative to the same construct transfected without PEI or with PEI 25 K, respectively. Moreover, PEI 2K-treated TF-1 and human CD34+ cells retained good viability. Collectively, these results indicate that PEI 2K at the optimal N/P ratio might be used to safely enhance gene delivery and transfection of hematopoietic and human CD34+ stem cells.     

Na+/H+ Exchangers and RhoA Regulate Acidic Extracellular pH-Induced Lysosome Trafficking in Prostate Cancer Cells

Acidic extracellular pH (pHe) is a common feature of the tumor microenvironment and has been implicated in tumor invasion through the induction of protease secretion. Since lysosomes constitute the major storehouse of cellular proteases, the trafficking of lysosomes to the cell periphery may be required in order to secrete proteases. We demonstrate that a pHe of 6.4-6.8 induced the trafficking of lysosomes to membrane protrusions in the cell periphery. This trafficking event depended upon the PI3K pathway, the GTPase RhoA and sodium-proton exchange activity, resulting in lysosomal exocytosis. Acidic pHe induced a cytoplasmic acidification (although cytoplasmic acidification was not sufficient for acidic pHe-induced lysosome trafficking and exocytosis) and inhibition of NHE activity with the amiloride derivative, EIPA or the anti-diabetic agent troglitazone prevented lysosome trafficking to the cell periphery. Interestingly, using the more specific NHE1 and NHE3 inhibitors, cariporide and s3226 respectively, we show that multiple NHE isoforms are involved in acidic pHe-induced lysosome trafficking and exocytosis. Moreover, in cells expressing NHE1 shRNA, although basal NHE activity was decreased, lysosomes still underwent acidic pHe-induced trafficking, suggesting compensation by other NHE family members. Together these data implicate proton exchangers, especially NHE1 and NHE3, in acidic pHe-induced lysosome trafficking and exocytosis.     

Enhanced gene transfer into brain capillary endothelial cells using Antp-modified DNA-loaded nanoparticles

Brain capillary endothelial cells (BCECs) have been considered as one of the primary targets for cerebral gene therapy. However, the cells, well-known for their poor function of endocytosis, are difficult to be transfected by general non-viral vectors. The aim of this study was to enhance the efficiency of transfection and expression in BCECs of DNA/polymer nanoparticles with the modification of membrane-penetrating peptide, Antennapedia peptide (Antp) polyethylenimine (PEI) and polyamidoamine (PAMAM) were chosen to prepare Antp-modified DNA-loaded nanoparticles with a complex coacervation technique. After a 20-min transfection, the efficiency, in terms of transfection and expression, of DNA/PEI NP or DNA/PAMAM NP was enhanced significantly with the modification of Antp. After a 3-h transfection of DNA/Antp/PEI NP, there was no difference in cellular uptake but an enhancement in gene expression, compared to DNA/PEI NP alone. However, both the transfection and expression efficiency of DNA/PAMAM NP were enhanced using Antp. These observations suggest that Antp can increase the membrane-penetrating ability of DNA-loaded nanoparticles, which can be employed as novel non-viral gene vectors.     

Intracellular processing and stability of DNA complexed with histidylated polylysine conjugates

Background

Glycosylated polylysines and histidylated polylysines complexed with plasmid DNA (pDNA) were proposed to develop polymer‐based gene delivery systems. The present work has been undertaken in two steps to study the uptake and the intracellular processing of pDNA, which are still poorly understood in the polyfection pathway.

Methods and results

The kinetics of the uptake and the intracellular processing of pDNA complexed with lactosylated polylysine, histidylated polylysine or histidylated polylysine bearing lactosyl residues (polyplexes) into a CF human airway epithelial cell line were assessed by flow cytometry and confocal microscopy. Complexes formed from histidylated polylysine, even though they were less taken up by cells, show better transfection efficiency with compared with lactosylated complexes. Lactosylated polymers segregated more rapidly when compared with non‐lactosylated polymers into compartments different from those containing pDNA on internalization. Intracellular location and pH measurements indicated that polymers ended up in compartments of pH ～6.2 while pDNA reached less acidic compartments of pH ～6.6. These compartments did not contain the LAMP‐1 lysosomal marker.

Conclusions

The present study exhibits that, upon internalization, pDNA and polylysine conjugates underwent segregation with a rate depending on the polylysine substitution and polymer degradation. The better transfection efficiency of polyplexes with histidylated polylysine can be ascribed to their prolonged stability inside the endocytic vesicles that likely favored the pDNA escape in the cytosol. Copyright © 2002 John Wiley & Sons, Ltd.

     

Endosomal escape of polymeric gene delivery complexes is not always enhanced by polymers buffering at low pH

One of the crucial steps in gene delivery with cationic polymers is the escape of the polymer/DNA complexes ("polyplexes") from the endosome. A possible way to enhance endosomal escape is the use of cationic polymers with a pKa around or slightly below physiological pH ("proton sponge"). We synthesized a new polymer with two tertiary amine groups in each monomeric unit [poly(2-methyl-acrylic acid 2-[(2-(dimethylamino)-ethyl)-methyl-amino]-ethyl ester), abbreviated as pDAMA]. One pKa of the monomer is approximately 9, providing cationic charge at physiological pH, and thus DNA binding properties, the other is approximately 5 and provides endosomal buffering capacity. Using dynamic light scattering and zeta potential measurements, it was shown that pDAMA is able to condense DNA in small particles with a surface charge depending on the polymer/DNA ratio. pDAMA has a substantial lower toxicity than other polymeric transfectants, but in vitro, the transfection activity of the pDAMA-based polyplexes was very low. The addition of a membrane disruptive peptide to pDAMA-based polyplexes considerably increased the transfection efficiency without adversely affecting the cytotoxicity of the system. This indicates that the pDAMA-based polyplexes alone are not able to mediate escape from the endosomes via the proton sponge mechanism. Our observations imply that the proton sponge hypothesis is not generally applicable for polymers with buffering capacity at low pH and gives rise to a reconsideration of this hypothesis.     

Linear topology confers in vivo gene transfer activity to polyethylenimines

Although polyethylenimines (PEIs) are frequently used transfection agents, it is still unclear which of their properties are required for efficient gene delivery. This is even more striking when working in vivo since some PEIs are able to generate significant gene expression, whereas others are not. To facilitate a rational development of compounds with improved transfection activities, studies aimed at identifying the properties involved in the transfection process seem indispensable. In the present work, we investigated how transfection with linear PEI of 22 kDa allows for high reporter gene expression in lungs after intravenous injection, whereas the branched PEI of 25 kDa does not. To this end, we synthesized L-PEI derivatives that are intermediates between linear and branched PEIs. Our results show that the topology plays a crucial role in obtaining in vivo reporter gene expression, whereas the content of primary, secondary, and tertiary amines is only of minor importance.     

The role of the cell cycle on the efficiency of photochemical gene transfection

The efficiency of gene transfection mediated by nonviral vectors is limited because of nonoptimal intracellular trafficking of transfecting DNA. Most nonviral vectors deliver transfecting DNA into a cell through endocytosis. However, poor escape from endocytic vesicles and inefficient transport of DNA into the nucleus often limits a success of gene transfection. Photochemical transfection is a new method, based on light-induced permeabilisation of endocytic vesicles, liberating transfecting DNA into the cytosol, concurrently increasing the chances for DNA to enter the nucleus.The aim of this study was to investigate the role of the cell cycle for the efficiency of photochemical transfection. It was demonstrated that in asynchronous human colon carcinoma HCT 116 cells photochemical treatment increased the transfection mediated by the nonviral vectors, the cationic polypeptide polylysine and the cationic lipid N-(2-aminoethyl)-N,N-dimethyl-2,3-bis(tetradecyloxy)-1-propanaminium bromide/dioleoylphosphatidylethanolamine (beta AE-DMRIE/DOPE), by 30- and 2.5-fold, respectively. In aphidicolin-synchronised cells, photochemical transfection mediated by polylysine was dependent on the cell cycle: transfection level was 4-fold higher when illumination, inducing photochemical reactions, was performed during the G2/M phase as compared to the G1/early-S phase. The cell cycle influence on photochemical transfection mediated by beta AE-DMRIE/DOPE was very low: only 20% difference between G2/M and the G1/S phase was observed. We suggest that transgenes, photochemically liberated close/during mitosis, perhaps have the highest opportunity to enter the nucleus and be expressed. However, the dependence of photochemical transfection on the cell cycle might be partially disguised by various factors induced by photochemical treatment.     

The use of low-molecular-weight PEIs as gene carriers in the monkey fibroblastoma and rabbit smooth muscle cell cultures

Background

Polyethylenimines (PEIs) and cationic polymers have been used successfully in gene delivery. In earlier reports, only large PEIs (MW>10 000) have shown significant transfection efficiency. In the present study, the roles of small PEIs (MW 700 and 2000) were studied as additional compounds to see if they can improve gene delivery with cationic liposomes.

Methods

The TKBPVlacZ expression plasmid was transfected in the CV1‐P (monkey fibroblastoma) and SMC (rabbit smooth muscle) cell lines using various combinations of PEIs (MW 700, 2000, and 25 000) and Dosper liposomes. The transfection efficiency was determined with the fluorometric ONPG (o‐nitrophenol‐β‐D ‐galactopyranoside) assay and histochemical X‐gal staining. The toxicity of the transfection reagents was estimated by the MTT [3‐(4,5‐dimethylthiazolyl‐2)‐2,5‐diphenyl tetrazolium bromide] assay.

Results

Transfection of TKBPVlacZ plasmid by the small PEIs (MW 700 and 2000) combined with Dosper liposomes was associated with high expression of the lacZ reporter gene in the CV1‐P and SMC cell lines. The transfection efficiencies of the low‐molecular‐weight PEI/liposome combinations were several fold higher than those of PEIs or liposomes alone. PEI/liposome combinations had no toxicity on the cell lines tested.

Conclusions

The low‐molecular‐weight PEIs could be used successfully for gene delivery when combined with the cationic liposomes, resulting in a synergistic increase of the transfection efficiency in both cell lines studied. Copyright © 2002 John Wiley & Sons, Ltd.

     

Acid‐activated nonviral peptide vector for gene delivery

Nonviral vector–based gene therapy is a promising strategy for treating a myriad of diseases. Cell‐penetrating peptides are gaining increasing attention as vectors for nucleic acid delivery. However, most studies have focused more on the transfection efficiency of these vectors than on their specificity and toxicity. To obtain ideal vectors with high efficiency and safety, we constructed the vector stearyl‐TH by attaching a stearyl moiety to the N‐terminus of the acid‐activated cell penetrating peptide TH in this study. Under acidic conditions, stearyl‐TH could bind to and condense plasmids into nanoparticle complexes, which displayed significantly enhanced cellular uptake and transfection efficiencies. In contrast, stearyl‐TH lost the capacities of DNA binding and transfection at physiological pH. More importantly, stearyl‐TH and the complexes formed by stearyl‐TH and plasmids displayed no obvious toxicity at physiological pH. Consequently, the high transfection efficiency under acidic conditions and low toxicity make stearyl‐TH a potential nucleic acid delivery vector for gene therapy.     

Single cell kinetics of intracellular, nonviral, nucleic acid delivery vehicle acidification and trafficking

Mechanistic understanding of the intracellular trafficking of nonviral nucleic acid delivery vehicles remains elusive. A live, single cell-based assay is described here that is used to investigate and quantitate the spatiotemporal, intracellular pH microenvironment of polymeric-based nucleic acid delivery vehicles. Polycations such as polyethylenimine (PEI), poly-l-lysine (PLL), beta-cyclodextrin-containing polymers lacking or possessing imidazole termini (CDP or CDP-imid), and cyclodextrin-grafted PEI (CD-PEI) are used to deliver an oligonucleotide containing a single fluorophore with two emission lines that can be employed to measure the pH. Delivery vehicles were also sterically stabilized by addition of poly(ethylene glycol) (PEG) and investigated. The intracellular trafficking data obtained via this new methodology show that vectors such as PEI and CDP-imid can buffer the endocytic vesicles while PLL and CDP do not. Additionally, the PEGylated vectors reveal the same buffering capacity as their unstabilized variants. Here, the live cell, spatiotemporal mapping of these behaviors is demonstrated and, when combined with cell uptake and luciferase expression data, shows that there is not a correlation between buffering capacity and gene expression.     

Low molecular weight hyaluronan shielding of DNA/PEI polyplexes facilitates CD44 receptor mediated uptake in human corneal epithelial cells

AIM: It was the aim of this study to prepare purified DNA/PEI polyplexes, which are coated with hyaluronan to facilitate CD44 receptor mediated uptake of the DNA/PEI polyplex and to reduce unspecific interactions of the complex with negatively charged extracellular matrix components on the ocular surface. METHODS: Hyaluronans of different molecular weights (<10 kDa, 10-30 kDa and 30-50 kDa) were isolated after enzymatic degradation of high molecular weight hyaluronan via ultrafiltration by centrifugation. The influence of the different hyaluronans used for coating on the stability and transfection efficiency of the complexes was evaluated in vitro. Transfection and uptake studies were performed in human corneal epithelial (HCE) cells. CD44 receptor expression of this cell model was evaluated by immunohistochemistry. RESULTS: Coating of purified DNA/PEI polyplexes with low molecular weight hyaluronan (<10 kDa) facilitated receptor-mediated uptake via the CD44 receptor in HCE cells, increased complex stability in vitro, and effectively shielded the positive surface charges of the polyplex without decreasing its transfection efficiency. Higher molecular weights and larger amounts of hyaluronan in the complexes resulted in lesser improvements in the stability and transfection efficacy of the complexes. CONCLUSIONS: Coating of polyplexes with low molecular weight hyaluronan is a promising strategy for gene delivery to the ocular surface, where CD44 receptor mediated uptake decreased cytotoxicity and reduced non-specific interactions with the negatively charged extracellular matrix components are considered beneficial for increased transfection efficiency of non-viral vectors.     

Preparation of a low molecular weight polyethylenimine for efficient cell transfection

Polyethylenimines (PEIs) of a molecular weight between 25 and about 800 kDa have successfully been used for in vitro and in vivo gene delivery approaches. Recent publications indicated that PEI molecules of lower molecular weight and a small molecular weight range are also efficient transfection reagents with a much lower cytotoxicity compared to high molecular weight PEIs. Here, we describe the application of a molecular sieve chromatography to fractionate a commercially available 25-kDa PEI. We generated three pools of PEIs with molecular weight ranges of 70-360 (I), 10-70 (II), and 0.5-10 kDa (III), respectively. We show that, in comparison with the 25-kDa PEI, pool III increased the expression of luciferase up to 100-fold and the number of transfected cells 2-3 fold. In addition, the kinetics of reporter gene expression was also much faster in pool III, compared with the 25-kDa PEI or with pools I or II. Finally, pool III showed the lowest cytotoxicity in comparison with the other PEI preparations. Thus, we provide a one-step processing of a 25-kDa PEI, resulting in a more effective and also less cytotoxic transfection reagent.