A universal description for the experimental behavior of salt-(in)dependent oligocation-induced DNA condensation

We report a systematic study of the condensation of plasmid DNA by oligocations with variation of the charge, Z, from +3 to +31. The oligocations include a series of synthetic linear ε-oligo(l-lysines), (denoted εKn, n = 3–10, 31; n is the number of lysines with the ligand charge Z = n+1) and branched α-substituted homologues of εK10: εYK10, εLK10 (Z = +11); εRK10, εYRK10 and εLYRK10 (Z = +21). Data were obtained by light scattering, UV absorption monitored precipitation assay and isothermal titration calorimetry in a wide range concentrations of DNA and monovalent salt (KCl, C_KCl). The dependence of EC₅₀ (ligand concentration at the midpoint of DNA condensation) on C_KCl shows the existence of a salt-independent regime at low C_KCl and a salt-dependent regime with a steep rise of EC₅₀ with increase of C_KCl. Increase of the ligand charge shifts the transition from the salt-independent to salt-dependent regime to higher C_KCl. A novel and simple relationship describing the EC₅₀ dependence on DNA concentration, charge of the ligand and the salt-dependent dissociation constant of the ligand–DNA complex is derived. For the ε-oligolysines εK6–εK10, the experimental dependencies of EC₅₀ on C_KCl and Z are well-described by an equation with a common set of parameters. Implications from our findings for understanding DNA condensation in chromatin are discussed.     

A universal description for the experimental behavior of salt-(in)dependent oligocation-induced DNA condensation

We report a systematic study of the condensation of plasmid DNA by oligocations with variation of the charge, Z, from +3 to +31. The oligocations include a series of synthetic linear ε-oligo(l-lysines), (denoted εKn, n = 3–10, 31; n is the number of lysines equal to the ligand charge) and branched α-substituted homologues of εK10: εYK10, εLK10 (Z = +10); εRK10, εYRK10 and εLYRK10 (Z = +20). Data were obtained by light scattering, UV absorption monitored precipitation assay and isothermal titration calorimetry in a wide range concentrations of DNA and monovalent salt (KCl, C_KCl). The dependence of EC₅₀ (ligand concentration at the midpoint of DNA condensation) on C_KCl shows the existence of a salt-independent regime at low C_KCl and a salt-dependent regime with a steep rise of EC₅₀ with increase of C_KCl. Increase of the ligand charge shifts the transition from the salt-independent to salt-dependent regime to higher C_KCl. A novel and simple relationship describing the EC₅₀ dependence on DNA concentration, charge of the ligand and the salt-dependent dissociation constant of the ligand–DNA complex is derived. For the ε-oligolysines εK3–εK10, the experimental dependencies of EC₅₀ on C_KCl and Z are well-described by an equation with a common set of parameters. Implications from our findings for understanding DNA condensation in chromatin are discussed.     

Biophysical properties and supramolecular structure of self-assembled liposome/ε-peptide/DNA nanoparticles: correlation with gene delivery

Using solid-phase synthesis, lysine can be oligomerized by a reaction of the peptide carboxylate with the ε-amino group to produce nontoxic, biodegradable cationic peptides, ε-oligo(L-lysines). Here α-substituted derivatives of such ε-oligo(L-lysines) containing arginine and histidine in the side chain were tested as vectors for in vitro gene delivery. Combination of ε-oligolysines with the cationic lipid DOTAP and plasmid DNA resulted in transfection efficiency exceeding that of DOTAP alone, without significant increase in cytotoxicity. Synchrotron small-angle X-ray scattering studies revealed self-assembly of the DOTAP, ε-oligolysines, and DNA to ordered lamellar complexes. High transfection efficiency of the nanoparticles correlates with increase in zeta potential above +20 mV and requires particle size to be below 500 nm. The synergistic effect of branched ε-oligolysines and DOTAP in gene delivery can be explained by the increase in surface charge and by the supramolecular structure of the DOTAP/ε-oligolysine/DNA nanoparticles.     

Dynamic condensation of linker histone C-terminal domain regulates chromatin structure

The basic and intrinsically disordered C-terminal domain (CTD) of the linker histone (LH) is essential for chromatin compaction. However, its conformation upon nucleosome binding and its impact on chromatin organization remain unknown. Our mesoscale chromatin model with a flexible LH CTD captures a dynamic, salt-dependent condensation mechanism driven by charge neutralization between the LH and linker DNA. Namely, at low salt concentration, CTD condenses, but LH only interacts with the nucleosome and one linker DNA, resulting in a semi-open nucleosome configuration; at higher salt, LH interacts with the nucleosome and two linker DNAs, promoting stem formation and chromatin compaction. CTD charge reduction unfolds the domain and decondenses chromatin, a mechanism in consonance with reduced counterion screening in vitro and phosphorylated LH in vivo. Divalent ions counteract this decondensation effect by maintaining nucleosome stems and expelling the CTDs to the fiber exterior. Additionally, we explain that the CTD folding depends on the chromatin fiber size, and we show that the asymmetric structure of the LH globular head is responsible for the uneven interaction observed between the LH and the linker DNAs. All these mechanisms may impact epigenetic regulation and higher levels of chromatin folding.     

Salt-dependent intra- and internucleosomal interactions of the H3 tail domain in a model oligonucleosomal array

The core histone tail domains are known to be key regulators of chromatin structure and function. The tails are required for condensation of nucleosome arrays into secondary and tertiary chromatin structures, yet little is known regarding tail structures or sites of tail interactions in chromatin. We have developed a system to test the hypothesis that the tails participate in internucleosomal interactions during salt-dependent chromatin condensation, and here we used it to examine interactions of the H3 tail domain. We found that the H3 tail participates primarily in intranucleosome interactions when the nucleosome array exists in an extended "beads-on-a-string" conformation and that tail interactions reorganize to engage in primarily internucleosome interactions as the array successively undergoes salt-dependent folding and oligomerization. These results indicated that the location and interactions of the H3 tail domain are dependent upon the degree of condensation of the nucleosomal array, suggesting a mechanism by which alterations in tail interactions may elaborate different structural and functional states of chromatin.     

Homogeneous reconstituted oligonucleosomes, evidence for salt-dependent folding in the absence of histone H1

Using the method of salt dialysis, we have reconstituted histone octamers onto DNA templates consisting of 12 tandem repeats, each containing a fragment of the sea urchin 5S rRNA gene [Simpson, R.T., Thoma, F., & Brubaker, J.M. (1985) Cell 42, 799-808]. In these templates, each sea urchin repeat contains a sequence for preferred nucleosome positioning. Sedimentation velocity and sedimentation equilibrium studies in the analytical ultracentrifuge indicate that at molar histone/DNA ratios of 1.0-1.1 extremely homogeneous preparations of fully loaded oligonucleosomes (12 nucleosomes/template) can be regularly obtained. Digestion of the oligonucleosomes with micrococcal nuclease, followed by restriction mapping of purified nucleosome-bound DNA sequences, yields a complicated but consistent pattern of nucleosome positioning. Roughly 50% of the nucleosomes appear to be phased at positions 1-146 of each repeat, while the remainder of the nucleosomes occupy a number of other minor discrete positions along the template that differ by multiples of 10 bp. From sedimentation velocity studies of the oligonucleosomes in 0-0.2 M NaCl, we observe a reversible increase in mean sedimentation coefficient by almost 30%, accompanied by development of heterogeneity in sedimentation. These results, in combination with theoretical predictions, indicate that linear stretches of chromatin in the absence of lysine-rich histones exist in solution in a salt-dependent equilibrium between an extended (low salt) conformation and one or more folded (high salt) structures. In addition, by 100 mM NaCl, salt-dependent dissociation of histone octamers from these linear oligonucleosomes is observed.     

Factors affecting DNA binding and stability of association to cationic liposomes

Lipoplexes are complexes formed between cationic liposomes (L(+)) and polyanionic nucleic acids (P(-)). They are commonly used in vitro and in vivo as a nucleic acid delivery system. Our study aims are to investigate how DOTAP-based cationic liposomes, which vary in their helper lipid (cholesterol or DOPE) and in media of different ionic strengths affect the degree, mode of association and degree of condensation of pDNA. This was determined by ultracentrifugation and gel electrophoresis, methods based on different physical principles. In addition, the degree of pDNA condensation was also determined using the ethidium bromide (EtBr) intercalation assay. The results suggest that for cationic lipid compositions (DOTAP/DOPE and DOTAP/cholesterol), 1.5 M NaCl, but not 0.15 M NaCl, both prevent lipoplex formation and/or induce partial dissociation between lipid and DNA of preformed lipoplexes. The higher the salt concentration the greater is the similarity of DNA condensation (monitored by EtBr intercalation) between lipoplex DNA and free DNA. As determined by ultracentrifugation and agarose gel electrophoresis, 30-90% of the DNA is uncondensed. SDS below its critical micellar concentration (CMC) induced "de-condensation" of DNA without its physical release (assessed by ultracentrifugation) for both DOTAP/DOPE and DOTAP/cholesterol lipoplexes. As was assessed by agarose gel electrophoresis SDS induced release of 50-60% of DNA from the DOTAP/cholesterol lipoplex but not from the DOTAP/DOPE lipoplex. This study shows that there are conditions under which DNA is still physically associated with the cationic lipids but undergoes unwinding to become less condensed. We also proved that the helper lipid affects level and strength of the L(+) and DNA(-) electrostatic association; these interactions are weaker for DOTAP/cholesterol than for DOTAP/DOPE, despite the fact that the positive charge and surface pH of DOTAP/cholesterol and DOTAP/DOPE are similar.     

Effect of salt on the binding of the linker histone H1 to DNA and nucleosomes

The linker histones are involved in the salt-dependent folding of the nucleosomes into higher-order chromatin structures. To better understand the mechanism of action of these histones in chromatin, we studied the interactions of the linker histone H1 with DNA at various histone/DNA ratios and at different ionic strengths. In direct competition experiments, we have confirmed the binding of H1 to superhelical DNA in preference to linear or nicked circular DNA forms. We show that the electrophoretic mobility of the H1/supercoiled DNA complex decreases with increasing H1 concentrations and increases with ionic strengths. These results indicate that the interaction of the linker histone H1 with supercoiled DNA results in a soluble binding of H1 with DNA at low H1 or salt concentrations and aggregation at higher H1 concentrations. Moreover, we show that H1 dissociates from the DNA or nucleosomes at high salt concentrations. By the immobilized template pull-down assay, we confirm these data using the physiologically relevant nucleosome array template.     

Interpreting protein/DNA interactions: distinguishing specific from non-specific and electrostatic from non-electrostatic components

We discuss the effectiveness of existing methods for understanding the forces driving the formation of specific protein-DNA complexes. Theoretical approaches using the Poisson-Boltzmann (PB) equation to analyse interactions between these highly charged macromolecules to form known structures are contrasted with an empirical approach that analyses the effects of salt on the stability of these complexes and assumes that release of counter-ions associated with the free DNA plays the dominant role in their formation. According to this counter-ion condensation (CC) concept, the salt-dependent part of the Gibbs energy of binding, which is defined as the electrostatic component, is fully entropic and its dependence on the salt concentration represents the number of ionic contacts present in the complex. It is shown that although this electrostatic component provides the majority of the Gibbs energy of complex formation and does not depend on the DNA sequence, the salt-independent part of the Gibbs energy--usually regarded as non-electrostatic--is sequence specific. The CC approach thus has considerable practical value for studying protein/DNA complexes, while practical applications of PB analysis have yet to demonstrate their merit.     

Hydrolysis of retinyl palmitate by enzymes of rat pancreas and liver. Differentiation of bile salt-dependent and bile salt-independent, neutral retinyl ester hydrolases in rat liver

Previous studies have demonstrated that homogenates of the livers of rats contain a neutral retinyl ester hydrolase activity that requires millimolar concentrations of bile salts for maximal in vitro activity. The enzymatic properties of this neutral, bile salt-dependent retinyl ester hydrolase activity in liver homogenates are nearly identical to those observed in the present report for the in vitro hydrolysis of retinyl palmitate by purified rat pancreatic cholesteryl ester hydrolase (EC 3.1.1.13). Moreover, anti-rat pancreatic cholesteryl ester hydrolase IgG completely inhibits the bile salt-dependent retinyl ester hydrolase activity of rat liver homogenates whereas normal rabbit IgG does not. We also show that liver homogenates contain a neutral, bile salt-independent retinyl ester hydrolase activity that differs from the bile salt-dependent activity in that 1) its absolute activity does not vary markedly among individual rats, 2) it is not inhibited by antibodies to pancreatic cholesteryl ester hydrolase, and 3) it is localized in the microsomal fraction of liver homogenates. Subfractionation of microsomes demonstrates that the neutral, bile salt-independent retinyl ester hydrolase activity is associated with liver cell plasma membranes and thus may play a role in the hydrolysis of retinyl esters delivered to the liver by chylomicron remnants.     

Nucleosome rearrangement in vitro. 2. Formation of nucleosomes in newly repaired regions of DNA

We have reported previously that immediately following nucleotide excision repair in human cells the newly repaired DNA lacks a nucleosome conformation [Smerdon, M. J., & Lieberman, M. W. (1980) Biochemistry 19, 2992-3000]. In this study, we have examined the ability of these nascent DNA regions to acquire a nucleosome structure in vitro by incubating intact or H1-depleted nuclei in buffers containing different salt concentrations (0.025-0.625 M KCl) at 0 or 37 degrees C. Nucleosomes were detected in these regions by an increase in the level of repair-incorporated nucleotides associated with isolated nucleosome core particle DNA. Our results indicate that the nascent DNA is resistant to nucleosome formation during the low-salt transition where the limiting repeat length decreases from approximately 190 to 168 base pairs (bp) [Watkins, J. F., & Smerdon, M. J. (1985) Biochemistry (preceding paper in this issue)]. This result provides further evidence that the nascent DNA is indeed in a nonnucleosomal state. At higher salt concentrations (greater than 0.4 M), where the nucleosome repeat length decreases to a limiting value of approximately 146 bp, there was an increase in nucleosome formation in nascent DNA that correlated with the decrease in limiting repeat length. However, we did not observe a complete randomization of the repair-incorporated nucleotides. Indeed, even at the highest salt concentration used (0.625 M), we never observed more than 50% of the nascent DNA associated with the isolated core particles. This was the case even though a major portion of the nucleosomes had a limiting value repeat length following the high-salt incubation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solution Scattering and FRET Studies on Nucleosomes Reveal DNA Unwrapping Effects of H3 and H4 Tail Removal

Using a combination of small-angle X-ray scattering (SAXS) and fluorescence resonance energy transfer (FRET) measurements we have determined the role of the H3 and H4 histone tails, independently, in stabilizing the nucleosome DNA terminal ends from unwrapping from the nucleosome core. We have performed solution scattering experiments on recombinant wild-type, H3 and H4 tail-removed mutants and fit all scattering data with predictions from PDB models and compared these experiments to complementary DNA-end FRET experiments. Based on these combined SAXS and FRET studies, we find that while all nucleosomes exhibited DNA unwrapping, the extent of this unwrapping is increased for nucleosomes with the H3 tails removed but, surprisingly, decreased in nucleosomes with the H4 tails removed. Studies of salt concentration effects show a minimum amount of DNA unwrapping for all complexes around 50-100mM of monovalent ions. These data exhibit opposite roles for the positively-charged nucleosome tails, with the ability to decrease access (in the case of the H3 histone) or increase access (in the case of the H4 histone) to the DNA surrounding the nucleosome. In the range of salt concentrations studied (0-200mM KCl), the data point to the H4 tail-removed mutant at physiological (50-100mM) monovalent salt concentration as the mononucleosome with the least amount of DNA unwrapping.     

Nucleosome dissociation and transfer in concentrated salt solutions.

We have examined the dissociation of nucleosomes into histones and free, 4.5S DNA over a range of sodium chloride concentrations between 0.25 and 1 M. We have also studied this dissociation as a function of nucleosome concentration at two salt concentrations, 0.8 M and 0.9 M. In addition, we have measured the kinetics of transfer of histone cores from nucleosomes onto recipient bacteriophage T7 DNA in 0.6, 0.7 and 0.8 M NaCl solutions. Although the mechanism of nucleosome transfer is unknown the data presented here are consistent with either a reversible dissociation of the nucleosome or DNA strand displacement by another DNA.     

Distamycin A affects the stability of NF-kappaB p50-DNA complexes in a sequence-dependent manner

The effect of two different DNA minor groove binding molecules, Hoechst 33258 and distamycin A, on the binding kinetics of NF-kappaB p50 to three different specific DNA sequences was studied at various salt concentrations. Distamycin A was shown to significantly increase the dissociation rate constant of p50 from the sequences PRDII (5'-GGGAAATTCC-3') and Ig-kappa B (5'-GGGACTTTCC-3') but had a negligible effect on the dissociation from the palindromic target-kappaB binding site (5'-GGGAATTCCC-3'). By comparison, the effect of Hoechst 33258 on binding of p50 to each sequence was found to be minimal. The dissociation rates for the protein--DNA complexes increased at higher potassium chloride concentrations for the PRDII and Ig-kappaB binding motifs and this effect was magnified by distamycin A. In contrast, p50 bound to the palindromic target-kappaB site with a much higher intrinsic affinity and exhibited a significantly reduced salt dependence of binding over the ionic strength range studied, retaining a K(D) of less than 10 pM at 150 mM KCl. Our results demonstrate that the DNA binding kinetics of p50 and their salt dependence is strongly sequence-dependent and, in addition, that the binding of p50 to DNA can be influenced by the addition of minor groove-binding drugs in a sequence-dependent manner.     

Poly(ADP-ribose) effectively competes with DNA for histone H4 binding

The effect of poly(ADP-ribose) on DNA-histone H4 interaction was studied using a nitrocellulose filter binding assay. Poly-(ADP-ribose) was found to form poly(ADP-ribose)-histone H4 complexes at physiological salt concentrations. The homopolymer effectively competed with DNA for histone H4 binding. Poly(ADP-ribose) was also capable of displacing DNA from preformed DNA-histone H4 complexes. Our hypothesis is that poly(ADP-ribose), locally and transiently formed at the site of DNA damage, causes dissociation of DNA from the nucleosome particle or nucleosome unfolding.     

Nucleosome rearrangement in vitro. 1. Two phases of salt-induced nucleosome migration in nuclei

We have investigated the salt- and temperature-induced rearrangement of nucleosomes in both intact and H1-depleted nuclei from human cells. In agreement with previous reports on the rearrangement of nucleosomes in isolated chromatin or chromatin fragments, we observed a decrease in the average nucleosome repeat length following incubation of nuclei at 37 degrees C in elevated salt concentrations. However, this decrease occurred in two distinct phases. First, incubation of H1-depleted nuclei at 37 degrees C for as little as 10 min in low-salt, isotonic buffer (containing 0.025 M KCl) resulted in a shift in the limiting repeat value from approximately 190 to 168 base pairs (bp). A similar shift was observed for intact nuclei incubated at 37 degrees C for 1 h in buffer containing near-physiological salt concentrations (i.e., 0.175 M KCl). This limiting repeat value was maintained in both intact and H1-depleted nuclei up to a salt concentration of 0.45 M KCl in the incubation buffer. Second, at salt concentrations of 0.625 M KCl, a limiting repeat of approximately 146 bp was obtained, and the nuclei had clearly lysed. During the first shift in repeat length, little additional exchange of nuclear proteins occurred compared to nuclei kept on ice in a low-salt buffer. This was the case even though the conditions used to monitor exchange were optimized by using a high DNA to chromatin ratio. On the other hand, a significant increase in the exchange of nuclear proteins, and formation of nucleosomes on the naked DNA, was observed during the shift in repeat length to 146 bp.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA bending due to specific p53 and p53 core domain-DNA interactions visualized by electron microscopy

We have used transmission electron microscopy to analyze the specificity and the extent of DNA bending upon binding of full-length wild-type human tumor suppressor protein p53 (p53) and the p53 core domain (p53CD) encoding amino acid residues 94-312, to linear double-stranded DNA bearing the consensus sequence 5'-AGACATGCCTAGACATGCCT-3' (p53CON). Both proteins interacted with high specificity and efficiency with the recognition sequence in the presence of 50 mM KCl at low temperature ( approximately 4 degrees C) while the p53CD also exhibits a strong and specific interaction at physiological temperature. Specific complex formation did not result in an apparent reduction of the DNA contour length. The interaction of p53 and the p53CD with p53CON induced a noticeable salt-dependent bending of the DNA axis. According to quantitative analysis with folded Gaussian distributions, the bending induced by p53 varied from approximately 40 degrees to 48 degrees upon decreasing of the KCl concentration from 50 mM to approximately 1 mM in the mounting buffer used for adsorption of the complexes to the carbon film surface. The p53CD bent DNA by 35-37 degrees for all salt concentrations used in the mounting buffer. The bending angle of the p53/DNA complex under low salt conditions showed a somewhat broader distribution (sigma approximately 39 degrees ) than at high salt concentration (sigma approximately 31 degrees ) or for p53CD (sigma approximately 24-27 degrees ). Together, these results demonstrate that the p53CD has a dominant role in complex formation and that the complexes formed both by p53 and p53CD under moderate salt conditions are similar. However, the dependence of the bending parameters on ambient conditions suggest that the segments flanking the p53CD contribute to complex formation as well. The problems associated with the analysis of bending angles in electron microscopy experiments are discussed.     

Aggregation of nucleosomes by divalent cations.

Conditions of precipitation of nucleosome core particles (NCP) by divalent cations (Ca(2+) and Mg(2+)) have been explored over a large range of nucleosome and cation concentrations. Precipitation of NCP occurs for a threshold of divalent cation concentration, and redissolution is observed for further addition of salt. The phase diagram looks similar to those obtained with DNA and synthetic polyelectrolytes in the presence of multivalent cations, which supports the idea that NCP/NCP interactions are driven by cation condensation. In the phase separation domain the effective charge of the aggregates was determined by measurements of their electrophoretic mobility. Aggregates formed in the presence of divalent cations (Mg(2+)) remain negatively charged over the whole concentration range. They turn positively charged when aggregation is induced by trivalent (spermidine) or tetravalent (spermine) cations. The higher the valency of the counterions, the more significant is the reversal of the effective charge of the aggregates. The sign of the effective charge has no influence on the aspect of the phase diagram. We discuss the possible reasons for this charge reversal in the light of actual theoretical approaches.     

Structure and internal organization of overcharged cationic-lipid/peptide/DNA self-assembly complexes

The combination of cationic lipids with cationic peptides and DNA vectors can produce synergistic effects in gene delivery to eukaryotic cells. Binary complexes of cationic lipids with DNA are well-studied whereas little information is available about the structure of the ternary lipid/peptide/DNA (LPD) complexes and mechanisms defining DNA protection and delivery. Here we use synchrotron small angle X-ray scattering and dynamic light scattering zeta-potential measurements to determine structure and the net charge of supramolecular aggregates of complexes in mixtures of plasmid DNA, cationic liposomes formed from DOTAP, plus a linear cationic ε-oligolysine with the pendant α-amino acids Leu-Tyr-Arg (LYR), ε-(LYR)K10. These ternary complexes display multilamellar structures with relatively constant separation between DOTAP bilayers, accommodating a hydrated monolayer of parallel DNA rods. The DNA-DNA distance in the complexes varies as a function of the net positive to negative (lipid+peptide)/DNA charge ratio. An explanation for the observed dependence of DNA-DNA distance on charge ratio was proposed based on general polyelectrolyte properties of non-stoichiometric polycation-DNA mixtures.