Star-shaped poly(ethylene glycol)-block-polyethylenimine copolymers enhance DNA condensation of low molecular weight polyethylenimines

Star-shaped poly(ethylene glycol)-block-polyethylenimine [star-(PEG-b-PEI)] significantly enhance plasmid DNA condensation of low molecular weight (MW) PEIs. The star-block copolymers were prepared via a facile synthesis route using hexamethylene diisocyanate as linker between PEG and PEI blocks. NMR and FT-IR spectroscopy confirmed the structures of intermediately activated PEG and final products. Furthermore, the copolymers were characterized by size exclusion chromatography, static light scattering, and viscosimetry. Their molecular weights (M(w) 19-26 kDa) were similar to high MW PEI (25 kDa). Thermoanalytical investigations (thermogravimetric analysis, differential scanning calorimetry) were also performed and verified successful copolymer synthesis. DNA condensation with the low MW PEIs (800 and 2000 Da) and their 4- and 8-star-block copolymers was studied using atomic force microscopy, dynamic light scattering, zeta-potential measurements, and ethidium bromide (EtBr) exclusion assay. It was found that low MW PEIs formed huge aggregates (500 nm to 2 microm) in which DNA is only loosely condensed. By contrast, the star-block copolymers yielded small (80-110 nm), spherical and compact complexes that were stable against aggregation even at high ionic strength and charge neutrality. Furthermore, as revealed in the EtBr exclusion assay these star-block copolymers exhibited a DNA condensation potential as high as high MW PEI. Since these star-(PEG-block-PEI) copolymers are composed of relatively nontoxic low MW PEI and biocompatible PEG, their potential as gene delivery agents merits further investigations.     

Molecular dynamics simulations of DNA/PEI complexes: effect of PEI branching and protonation state

Complexes formed by DNA and polyethylenimine (PEI) are of great research interest because of their application in gene therapy. In this work, we carried out all-atom molecular dynamics simulations to study eight types of DNA/PEI complexes, each of which was formed by one DNA duplex d(CGCGAATTCGCG)₂ and one PEI. We used eight different PEIs with four different degrees of branching and two protonation ratios of amine groups (23% and 46%) in the simulations to investigate how the branching degree and protonation state can affect the binding. We found that 46% protonated PEIs form more stable complexes with DNA, and the binding is achieved mainly through direct interaction between the protonated amine groups on PEI and the electronegative oxygens on the DNA backbone, with some degree of interaction with electronegative groove nitrogens/oxygens. For the 23% protonated PEIs, indirect interaction mediated by one or more water molecules plays an important role in binding. Compared with the protonation state, the degree of branching has a smaller effect on binding, which essentially diminishes at the protonation ratio of 46%. These simulations shed light on the detailed mechanism(s) of PEI binding to DNA, and may facilitate the design of PEI-based gene delivery carriers.     

Efficient gene transfer using reversibly cross-linked low molecular weight polyethylenimine.

Polyethylenimine (PEI) is a polycation with potential application as a nonviral vector for gene delivery. Here we show that after conjugation with homobifunctional amine reactive reducible cross-linking reagents, low molecular weight polyethylenimine efficiently mediates in vitro gene delivery to Chinese hamster ovary (CHO) cells. Two cross-linking reagents, dithiobis(succinimidylpropionate) (DSP) and dimethyl.3,3'-dithiobispropionimidate*2HCl (DTBP), were utilized based on their reactivity and chemical properties. Both reagents react with primary amines to form reducible cross-links; however, unlike DSP, the DTBP cross-linker maintains net polymer charge through amidine bond formation. PEI with a reported weight-average molecular weight (M(w)) of 800 Da was reacted with either DSP or DTBP at PEI primary amine:cross-link reactive group ratios of 1:1 and 2:1. The transfection efficiencies of the resulting cross-linked products were evaluated in CHO cells using a luciferase reporter gene under a cytomegalovirus (CMV) promoter. Our results show that cross-linked polymers mediate variable levels of transfection depending on the cross-linking reagent, the extent of conjugation, and the N/P ratio. In general, we found conjugate size to be proportional to gene transfer efficiency. Using gel retardation analysis, we also evaluate the capacity of the cross-linked polymers to condense plasmid DNA before and after reduction with 45 mM dithiothreitol (DTT). DTT mediated reduction of intra-cross-link disulfide bonds and inhibited condensation of DNA by conjugates cross-linked with DSP at a ratio of 1:1, but had little effect on the remaining polymers. Analogous intracellular reduction of transfection complexes by reduced glutathione could facilitate uncoupling of PEI from DNA to enhance gene expression.     

Exploring polyethylenimine-mediated DNA transfection and the proton sponge hypothesis

BACKGROUND: The relatively high transfection efficiency of polyethylenimine (PEI) vectors has been hypothesized to be due to their ability to avoid trafficking to degradative lysosomes. According to the proton sponge hypothesis, the buffering capacity of PEI leads to osmotic swelling and rupture of endosomes, resulting in the release of the vector into the cytoplasm. METHODS: The mechanism of PEI-mediated DNA transfer was investigated using quantitative methods to study individual steps in the overall transfection process. In addition to transfection efficiency, the cellular uptake, local pH environment, and stability of vectors were analyzed. N-Quaternized (and therefore non-proton sponge) versions of PEI and specific cell function inhibitors were used to further probe the proton sponge hypothesis. RESULTS: Both N-quaternization and the use of bafilomycin A1 (a vacuolar proton pump inhibitor) reduced the transfection efficiency of PEI by approximately two orders of magnitude. Chloroquine, which buffers lysosomes, enhanced the transfection efficiency of N-quaternized PEIs and polylysine by 2-3-fold. In contrast, chloroquine did not improve the transfection efficiency of PEI. The measured average pH environment of PEI vectors was 6.1, indicating that they successfully avoid trafficking to acidic lysosomes. Significantly lower average pH environments were observed for permethyl-PEI (pH 5.4), perethyl-PEI (pH 5.1), and polylysine (pH 4.6) vectors. Cellular uptake levels of permethyl-PEI and perethyl-PEI vectors were found to be 20 and 90% higher, respectively, than that of parent PEI vectors, indicating that the reduction in transfection activity of the N-quaternized PEIs is due to a barrier downstream of cellular uptake. A polycation/DNA-binding affinity assessment showed that the more charge dense N-quaternized PEIs bind DNA less tightly than PEI, demonstrating that poor vector unpackaging was not responsible for the reduced transfection activity of the N-quaternized PEIs. CONCLUSIONS: The results obtained are consistent with the proton sponge hypothesis and strongly suggest that the transfection activity of PEI vectors is due to their unique ability to avoid acidic lysosomes.     

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.     

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.     

Gene transfer with modified polyethylenimines

Branched and linear polyethylenimines (PEIs) have proven to be efficient and versatile agents for gene delivery in vitro. In addition, systemic administration of positively charged DNA/PEI complexes results in significant reporter gene expression in lungs. However, re-targeting of complexes to organs other than the lung is hampered by non-specific interactions of polyplexes with blood components and non-target cells. Thus, despite considerable transfectional activity, the properties of PEIs need to be further improved. Therefore, various modifications of PEIs have been explored in recent years. For example, to increase the circulation half-life of the DNA complexes, the surface charge of the particles was shielded by grafting hydrophilic polymers such as polyethylene glycols (PEGs) onto their surface. Alternatively, incorporation of certain ligands into the DNA complexes also resulted in charge shielding even without PEGylation. Herein, I review the most recent PEI derivatives, with a special focus on PEGylated and targeted polymers.     

Triple interpolyelectrolyte complexes DNA-polycation-polyanion: a new approach to optimization of mixtures for transfection in eukaryotic cells

A new approach to optimization of mixtures for the condensation and introduction of plasmid DNA into eukaryotic cells is proposed, which is based on the formation of ternary interpolyelectrolyte complexes (IPEC) DNA/polycation/polyanion. Polyethyleneimine (PEI) with M 30-40 kDa as polycation and polyacrylic acid (PA) with M 20 kDa or its grafted copolymer with polyethyleneglycol (PEG) as polyanion were used, and ternary complexes with various ratios of the components were prepared. The PA-PEG incorporation into a ternary complex (by itself or as a 1:1 mixture with PA) was shown to confer the solubility onto complexes in a wide range of DNA/PEI ratios. Incorporation of even minute amounts of PA-PEG (as a 1:9 mixture with PA), while not completely preventing the aggregation of ternary IPEC, drastically changed their sorption characteristics. Using a beta-galactosidase-encoding plasmid, efficiencies of transfection of the CHO-AA8 and 293 cells for different IPEC and DNA/lipofectin complex were compared. The maximum efficiency was exhibited by ternary complex DNA/PEI/polyanion where a 1:1 mixture of PA and PA-PEG was used as polyanion. Possible reasons for this effect and further ways of optimization of mixtures for expression of plasmid DNA in the context of the new approach are discussed.     

Probing the effects of lipid substitution on polycation mediated DNA aggregation: a molecular dynamics simulations study

Understanding the molecular mechanism of DNA aggregation and condensation is of importance to DNA packaging in cells, and applications of gene delivery therapy. Modifying polycations such as polyethylenimine with lipid substitution was found to improve the performance of polycationic gene carriers. However, the role of the lipid substitution in DNA binding and aggregation is not clear and remains to be probed at the molecular level. In this work, we elucidated the role of lipid substitution through a series of all-atom molecular dynamics simulations on DNA aggregation mediated by lipid modified polyethylenimine (lmPEI). We found that the lipids associate significantly with one another, which links the lmPEIs and serves as a mechanism of aggregating the DNAs and stabilizing the formed polyplex. In addition, some lipid tails on the lmPEIs stay at the periphery of the lmPEI/DNA polyplex and may provide a mechanism for hydrophobic interactions. The enhanced stability and hydrophobicity might contribute to better cellular uptake of the polyplexes.     

Layer-by-layer deposition of oppositely charged polyelectrolytes on the surface of condensed DNA particles.

DNA can be condensed with an excess of poly-cations in aqueous solutions forming stable particles of submicron size with positive surface charge. This charge surplus can be used to deposit alternating layers of polyanions and polycations on the surface surrounding the core of condensed DNA. Using poly-L-lysine (PLL) and succinylated PLL (SPLL) as polycation and polyanion, respectively, we demonstrated layer-by-layer architecture of the particles. Polyanions with a shorter carboxyl/backbone distance tend to disassemble binary DNA/PLL complexes by displacing DNA while polyanions with a longer carboxyl/backbone distance effectively formed a tertiary complex. The zeta potential of such complexes became negative, indicating effective surface recharging. The charge stoichiometry of the DNA/PLL/SPLL complex was found to be close to 1:1:1, resembling poly-electrolyte complexes layered on macrosurfaces. Recharged particles containing condensed plasmid DNA may find applications as non-viral gene delivery vectors.     

Efficient Gene Delivery Using Anionic Liposome-Complexed Polyplexes (LPDII)

Synthetic gene transfer vectors based on polyplexes complexed to anionic liposomes (LPDII vectors) were characterized for their transfection efficiency in cultured mammalian cells. The effects of polycation to DNA ratio, lipid to DNA ratio, choice of polycation and lipid composition were systematically evaluated in human oral carcinoma KB cells, using a luciferase reporter gene. For LPDII formulations containing poly-L-lysine and dioeoylphosphatidylethanolamine/cholesteryl hemisuccinate (DOPE/CHEMS) anionic liposomes, at a constant lipid to DNA ratio, an increase in the polycation/DNA (N/P) ratio resulted in an increase in transfection activity. Meanwhile, the optimal lipid to DNA ratio for efficient gene delivery was influenced by the N/P ratio used, and was increased at higher N/P ratios. For the DNA condensing agent, poly-L-lysine could be replaced by polyethylenimine (PEI) as the DNA condensing agent in the formulations. For the lipidic components, CHEMS could be replaced by other anioniclipids including oleic acid, dicetylphosphate and phosphatidylserine, but DOPE, a fusogenic helper lipid, could not be replaced by dioleolyphosphatidylcholine. LPDII formulation showed significantly less cytotoxicity compared to the commonly used cationic lipsomes or PEI mediated transfection and several cell lines were transfected with high efficiency. LPDII vectors avoid the use of toxic cationic lipids and may have potential application in gene therapy.     

Poly(ethyleneimine)-mediated large-scale transient gene expression: influence of molecular weight, polydispersity and N-propionyl groups

Three synthesis lots of linear poly(ethyleneimine) (PEI) are compared to a fully hydrolyzed linear PEI (commercially available as PEI "Max") regarding structure, polyplex formation with plasmid DNA, and transfection of suspension-adapted HEK-293E cells. PEI "Max" binds DNA more efficiently than the other PEIs, but it is the least effective in terms of transient recombinant protein yield. One PEI lot is fractionated by means of SEC. The fractions of high-M(n) PEI are the most efficient for complex formation and transfection. Nevertheless, the highest transient recombinant protein yields are achieved with unfractionated PEI. The results demonstrate that the polydispersity and charge density of linear PEI are important parameters for gene delivery to suspension-adapted HEK-293E cells.     

Ternary Interpolyelectrolyte Complexes DNA–Polycation–Polyanion: A New Approach to Optimization of Mixtures for Transfection of Eukaryotic Cells

A new approach to optimization of mixtures for the condensation and introduction of plasmid DNA into eukaryotic cells is proposed, which is based on the formation of ternary interpolyelectrolyte complexes (IPEC) DNA/polycation/polyanion. Polyethyleneimine (PEI) with M30–40 kDa as polycation and polyacrylic acid (PA) with M20 kDa or its grafted copolymer with polyethyleneglycol (PEG) as polyanion were used, and ternary complexes with various ratios of the components were prepared. The PA–PEG incorporation into a ternary complex (by itself or as a 1 : 1 mixture with PA) was shown to confer the solubility onto complexes in a wide range of DNA/PEI ratios. Incorporation of even minute amounts of PA–PEG (as a 1 : 9 mixture with PA), while not completely preventing the aggregation of ternary IPEC, drastically changed their sorption characteristics. Using a -galactosidase-encoding plasmid, efficiencies of transfection of the CHO-AA8 and 293 cells for different IPEC and DNA/lipofectin complex were compared. The maximum efficiency was exhibited by ternary complex DNA/PEI/polyanion where a 1 : 1 mixture of PA and PA–PEG was used as polyanion. Possible reasons for this effect and further ways of optimization of mixtures for expression of plasmid DNA in the context of the new approach are discussed.     

Ternary complex consisting of DNA, polycation, and a natural polysaccharide of schizophyllan to induce cellular uptake by antigen presenting cells

A natural polysaccharide called schizophyllan (SPG) can form a complex with polynucleotides, and the complex has been shown to deliver biofunctional short DNAs such as antisense DNAs and CpG-DNAs. Although it is a novel and efficient method, there is a drawback: attachment of homo-polynucleotide tails [for example, poly(dA) or poly(C)] to the end of DNA is necessary to stabilize the complex, because DNA heterosequences cannot bind to SPG. The aim of this paper is to present an alternative method in which SPG/DNA complexes can be made without using the tails. The basic strategy is as follows: since SPG can form hydrophobic domains in aqueous solutions, hydrophobic objects should be encapsulated by this domain. DNA alone is highly hydrophilic; however, once DNA/polycation complexes are made, they should be included by the SPG hydrophobic domain. The aim of this paper is to prove the formation of the polycation/DNA/SPG ternary complex. Gel electrophoresis showed that presence of SPG influenced the migration pattern of polycation+DNA mixtures. With increasing the SPG ratio, the zeta potential (zeta) of the polycation+DNA+SPG mixture decreased drastically to reach almost zeta = 0 and the particle size distributions were altered due to the ternary complex formation. Confocal laser scanning microscopy revealed that the polycation/DNA/SPG ternary complexes showed high uptake efficiency when the complexes were exposed to macrophage-like cells (J774.A1). IL-12 secretion was enhanced when CpG-DNA was added as the ternary complex. These features can be ascribed to the fact that J774.A1 has a SPG recognition site called Dectin-1 on the cellular surface and the ternary complex can be ingested by this pathway.     

Phosphodiester and phosphorothioate oligonucleotide condensation and preparation of antisense nanoparticles

Protamine is a cationic peptide with a molecular mass of approx. 4000 Da that is able to condense DNA. In the present study it was used to complex antisense oligonucleotides (ODNs) and to form solid particles with initial diameters of 90-150 nm. The reaction was very rapid and occurred by simple mixing of diluted solutions of the polycation with the oligonucleotide. The aggregation was dependent on the oligonucleotide chain length and the protamine/ODN mass ratio. Particle formation required a minimal chain length of nine nucleotides and a mass ratio of 0.5:1. The particle surface charge and the number of particles depended on the mass ratio. With increasing amounts of the peptide, the number of particles and the zeta potential increased. Both negatively and positively charged particles improved the stability of oligonucleotides against DNase I digestion. Above a mass ratio of 2.5:1 no degradation was found. The uptake of unbound rhodamine-labelled ODNs and its complexes with protamine was determined with Vero cells under in vitro cell culture conditions at 37 degrees C and 4 degrees C. At 37 degrees C the cellular uptake increased with increasing mass ratio. The internalized oligonucleotides were localized in the cytoplasm and in the nucleus of the cells. When Vero cells were treated with these samples at 4 degrees C for 4 h, no fluorescence could be detected inside the cells. Therefore, our data indicate an energy dependent endocytotic uptake mechanism. In contrast, spermine and spermidine, which are also known condensation agents, did not aggregate with oligonucleotides into nanoparticles under the same conditions.     

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.     

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.     

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.     

Polymorphism of the SOD1-DNA aggregation species can be modulated by DNA

Proteinaceous aggregates rich in copper, zinc superoxide dismutase (SOD1) have been found in both in vivo and in vitro models. We have shown that double-stranded DNA that acts as a template accelerates the in vitro formation of wild-type SOD1 aggregates. Here, we examined the polymorphism of templated-SOD1 aggregates generated in vitro upon association with DNA under different conditions. Electron microscopy imaging indicates that this polymorphism is capable of being manipulated by the shapes, structures, and doses of the DNAs tested. The nanometer- and micrometer-scale aggregates formed under acidic conditions and under neutral conditions containing ascorbate fall into three classes: aggregate monomers, oligomeric aggregates, and macroaggregates. The aggregate monomers observed at given DNA doses exhibit a polymorphism that is markedly corresponded to the coiled shapes of linear DNA and structures of plasmid DNA. On the other hand, the regularly branched structures observed under both atomic force microscopy and optical microscope indicate that the DNAs tested are simultaneously condensed into a nanoparticle with a specific morphology during SOD1 aggregation, revealing that SOD1 aggregation and DNA condensation are two concurrent phenomena. The results might provide the basis of therapeutic approaches to suppress the formation of toxic protein oligomers or aggregates by screening the toxicity of the protein aggregates with various sizes and morphologies.