Poly(L-Lysine)-Graft-Dextran Copolymer Remarkably Promotes Pyrimidine-Motif Triplex Formation at Neutral Ph: Thermodynamic and Kinetic Studies

Abstract

The binding constant of a homopyrimidine oligonucleotide with its target duplex for the pyrimidine-motif triplex formation at neutral pH was analyzed and found to be remarkably higher in the presence of the poly (L-lysine)-graft-dextran copolymer than that without any triplex stabilizer or in the presence of spermine. The promoting effect mainly results from the considerable increase in the association rate constant.     

Poly(L-lysine)-graft-dextran copolymer promotes pyrimidine motif triplex DNA formation at physiological pH. Thermodynamic and kinetic studies

Extreme instability of pyrimidine motif triplex DNA at physiological pH severely limits its use for artificial control of gene expression in vivo. Stabilization of the pyrimidine motif triplex at physiological pH is therefore of great importance in improving its therapeutic potential. To this end, isothermal titration calorimetry interaction analysis system and electrophoretic mobility shift assay have been used to explore the thermodynamic and kinetic effects of our previously reported triplex stabilizer, poly (L-lysine)-graft-dextran (PLL-g-Dex) copolymer, on pyrimidine motif triplex formation at physiological pH. Both the thermodynamic and kinetic analyses have clearly indicated that in the presence of the PLL-g-Dex copolymer, the binding constant of the pyrimidine motif triplex formation at physiological pH was about 100 times higher than that observed without any triplex stabilizer. Of importance, the triplex-promoting efficiency of the copolymer was more than 20 times higher than that of physiological concentrations of spermine, a putative intracellular triplex stabilizer. Kinetic data have also demonstrated that the observed copolymer-mediated promotion of the triplex formation at physiological pH resulted from the considerable increase in the association rate constant rather than the decrease in the dissociation rate constant. Our results certainly support the idea that the PLL-g-Dex copolymer could be a key material and may eventually lead to progress in therapeutic applications of the antigene strategy in vivo.     

Thermodynamic and kinetic effects of N3'-->P5' phosphoramidate modification on pyrimidine motif triplex DNA formation

I have investigated the thermodynamic and kinetic effects of N3'-->P5' phosphoramidate (PN) backbone modification of triplex-forming oligonucleotide (TFO) on the pyrimidine motif triplex formation between a 23-bp target duplex and a 15-mer TFO using electrophoretic mobility shift assay, UV melting, isothermal titration calorimetry, and interaction analysis system. The thermodynamic and kinetic analyses have clearly indicated that the PN modification of TFO not only significantly increased the thermal stability of the pyrimidine motif triplex at neutral pH but also increased the binding constant of the pyrimidine motif triplex formation at room temperature and neutral pH by nearly 2 orders of magnitude. The consideration of the observed thermodynamic parameters has suggested that the more rigidity of the PN TFO in the free state relative to the unmodified TFO may enable the significant increase in the binding constant of the pyrimidine motif triplex formation at neutral pH. Kinetic data have also demonstrated that the observed PN modification-mediated promotion of pyrimidine motif triplex formation at neutral pH resulted from the considerable decrease in the dissociation rate constant rather than the increase in the association rate constant. This information will present an effective approach for designing chemically modified TFO with higher binding affinity in the triplex formation under physiological conditions, which may eventually lead to progress in therapeutic applications of the antigene strategy in vivo.     

Triplex formation using ODN conjugates with polycation comb-type copolymer.

Polycation comb-type copolymer that is composed of polylysine backbone and dextran side chains (PLL-g-Dex) has previously been shown to stabilize duplex and triplex DNAs quite effectively. In this study, we have conjugated PLL-g-Dex with oligonucleotides (ODN) aiming to increase the triplex stabilizing efficiency of the copolymer. Here we have demonstrated that the copolymer-TFO conjugates selectively stabilize triplex DNA. Also its potential to form triplex DNA was found to be greater than PLL-g-Dex/ODN mixture.     

2'-O,4'-C-methylene bridged nucleic acid modification promotes pyrimidine motif triplex DNA formation at physiological pH: thermodynamic and kinetic studies

Extreme instability of pyrimidine motif triplex DNA at physiological pH severely limits its use in an artificial control of gene expression in vivo. Stabilization of the pyrimidine motif triplex at physiological pH is, therefore, crucial in improving its therapeutic potential. To this end, we have investigated the thermodynamic and kinetic effects of our previously reported chemical modification, 2'-O,4'-C-methylene bridged nucleic acid (2',4'-BNA) modification of triplex-forming oligonucleotide (TFO), on pyrimidine motif triplex formation at physiological pH. The thermodynamic analyses indicated that the 2',4'-BNA modification of TFO increased the binding constant of the pyrimidine motif triplex formation at neutral pH by approximately 20 times. The number and position of the 2',4'-BNA modification introduced into the TFO did not significantly affect the magnitude of the increase in the binding constant. The consideration of the observed thermodynamic parameters suggested that the increased rigidity itself of the 2',4'-BNA-modified TFO in the free state relative to the unmodified TFO may enable the significant increase in the binding constant at neutral pH. Kinetic data demonstrated that the observed increase in the binding constant at neutral pH by the 2',4'-BNA modification of TFO resulted from the considerable decrease in the dissociation rate constant. Our results certainly support the idea that the 2',4'-BNA modification of TFO could be a key chemical modification and may eventually lead to progress in therapeutic applications of the antigene strategy in vivo.     

2'-O,4'-C-ethylene bridged nucleic acid modification enhances pyrimidine motif triplex-forming ability under physiological condition

Since pyrimidine motif triplex DNA is unstable at physiological neutral pH, triplex stabilization at physiological neutral pH is important for improvement of its potential to be applied to various methods in vivo, such as repression of gene expression, mapping of genomic DNA and gene-targeted mutagenesis. For this purpose, we studied the thermodynamic and kinetic effects of a chemical modification, 2'-O,4'-C-ethylene bridged nucleic acid (ENA) modification of triplex-forming oligonucleotide (TFO), on pyrimidine motif triplex formation at physiological neutral pH. Thermodynamic investigations indicated that the modification achieved more than 10-fold increase in the binding constant of the triplex formation. The increased number of the modification in TFO enhanced the increased magnitude of the binding constant. On the basis of the obtained thermodynamic parameters, we suggested that the remarkably increased binding constant by the modification may result from the increased stiffness of TFO in the unbound state. Kinetic studies showed that the considerably decreased dissociation rate constant resulted in the observed increased binding constant by the modification. We conclude that ENA modification of TFO could be a useful chemical modification to promote the triplex formation under physiological neutral condition, and may advance various triplex formation-based methods in vivo.     

Promotion of triplex formation by a fixed N-form sugar puckering: thermodynamic and kinetic studies.

We analyzed the effect of a fixed N-form sugar puckering of TFO (triplex-forming oligonucleotide) on the pyrimidine motif triplex formation at neutral pH, a condition where pyrimidine motif triplexes are unstable. Both thermodynamic and kinetic analyses revealed that the binding constant of the pyrimidine motif triplex formation at pH 6.8 with modified TFO containing the fixed N-form sugar puckering was about 20-times larger than that observed with unmodified TFO. Kinetic data also demonstrated that the observed increase in the binding constant at neutral pH by the fixed N-form sugar puckering resulted from the considerable decrease in the dissociation rate constant. Our results certainly support the idea that the fixed N-form sugar puckering of TFO could be a key modification and may eventually lead to progress in therapeutic applications of the antigene strategy in vivo.     

PROMOTION OF TRIPLEX FORMATION BY 2′-O,4′-C-METHYLENE BRIDGED NUCLEIC ACID (2′,4′-BNA) MODIFICATION: THERMODYNAMIC AND KINETIC STUDIES

We analyzed the effect of 2′-O,4′-C-methylene bridged nucleic acid (2′,4′-BNA) modification of triplex-forming oligonucleotide (TFO) on pyrimidine motif triplex formation at neutral pH, a condition where pyrimidine motif triplexes are unstable. The binding constant of the pyrimidine motif triplex formation at pH 6.8 with 2′,4′-BNA modified TFO was about 20 times larger than that observed with unmodified TFO. The observed increase in the binding constant at neutral pH by the 2′,4′-BNA modification resulted from the considerable decrease in the dissociation rate constant.     

Promotion of triplex formation by 2'-O,4'-C-methylene bridged nucleic acid (2',4'-BNA) modification: thermodynamic and kinetic studies

We analyzed the effect of 2'-O,4'-C-methylene bridged nucleic acid (2',4'-BNA) modification of triplex-forming oligonucleotide (TFO) on pyrimidine motif triplex formation at neutral pH, a condition where pyrimidine motif triplexes are unstable. The binding constant of the pyrimidine motif triplex formation at pH 6.8 with 2',4'-BNA modified TFO was about 20 times larger than that observed with unmodified TFO. The observed increase in the binding constant at neutral pH by the 2',4'-BNA modification resulted from the considerable decrease in the dissociation rate constant.     

Presence of divalent cation is not mandatory for the formation of intramolecular purine-motif triplex containing human c-jun protooncogene target

Modulation of endogenous gene function, through sequence-specific recognition of double helical DNA via oligonucleotide-directed triplex formation, is a promising approach. Compared to the formation of pyrimidine motif triplexes, which require relatively low pH, purine motif appears to be the most gifted for their stability under physiological conditions. Our previous work has demonstrated formation of magnesium-ion dependent highly stable intermolecular triplexes using a purine third strand of varied lengths, at the purine?pyrimidine (Pu?Py) targets of SIV/HIV-2 (vpx) genes (Svinarchuk, F., Monnot, M., Merle, A., Malvy, C., and Fermandjian, S. (1995) Nucleic Acids Res. 23, 3831-3836). Herein, we show that a designed intramolecular version of the 11-bp core sequence of the said targets, which also constitutes an integral, short, and symmetrical segment (G(2)AG(5)AG(2))?(C(2)TC(5)TC(2)) of human c-jun protooncogene forms a stable triplex, even in the absence of magnesium. The sequence d-C(2)TC(5)TC(2)T(5)G(2)AG(5)AG(2)T(5)G(2)AG(5)AG(2) (I-Pu) folds back twice onto itself to form an intramolecular triple helix via a double hairpin formation. The design ensures that the orientation of the intact third strand is antiparallel with respect to the oligopurine strand of the duplex. The triple helix formation has been revealed by non-denaturating gel assays, UV-thermal denaturation, and circular dichroism (CD) spectroscopy. The monophasic melting curve, recorded in the presence of sodium, represented the dissociation of intramolecular triplex to single strand in one step; however, the addition of magnesium bestowed thermal stability to the triplex. Formation of intramolecular triple helix at neutral pH in sodium, with or without magnesium cations, was also confirmed by gel electrophoresis. The triplex, mediated by sodium alone, destabilizes in the presence of 5'-C(2)TC(5)TC(2)-3', an oligonucleotide complementary to the 3'-oligopurine segments of I-Pu, whereas in the presence of magnesium the triplex remained impervious. CD spectra showed the signatures of triplex structure with A-like DNA conformation. We suggest that the possible formation of pH and magnesium-independent purine-motif triplexes at genomic Pu?Py sequences may be pertinent to gene regulation.     

Mechanism of intermolecular purine-purine-pyrimidine triple helix stabilization by comb-type polylysine graft copolymer at physiologic potassium concentration

We previously reported a novel strategy to stabilize purine motif triplex DNA within a mammalian gene promoter at physiologically relevant pH, temperature, and potassium (K(+)) concentrations by a comb-type poly(L-lysine)-graft-dextran copolymer [Ferdous et al., (1998) Nucleic Acids Res. 26, 3949-3954]. Here we describe the major contribution(s) of the copolymer to stabilize the purine motif triplex DNA at physiological K(+) concentrations. Self-aggregation through guanine-quartet formation of guanine-rich (G-rich) triplex-forming oligonucleotides (TFOs) has long been proposed for K(+)-mediated inhibition of the purine motif triplex formation. However, this was not the case for the severe inhibitory effect of K(+) observed under our reaction conditions. Rather significant decrease in rate of triplex formation involving a G-rich TFO was a major factor to confer K(+) inhibition. Interestingly, in the presence of the copolymer the rate of triplex formation was tremendously increased and K(+)-induced dissociation of preformed triplexes was not observed. Moreover, the triplex-promoting/stabilizing efficiency of the copolymer was amazingly higher than that of physiological concentrations of spermine. An absolute increase in binding constant of the TFO to the target duplex could therefore be the predominant mechanistic source for the copolymer-mediated triplex stabilization under physiological conditions in vitro.     

Nodule DNA in the (GA)37.(CT)37 insert in superhelical plasmids.

Di- or trivalent metal ions stabilize a supercoil-dependent transition in pGA37, which contains the (GA)37.(CT)37 insert, at neutral and basic pH. The structure formed is different from the well known protonated triplexes (H-DNA) adopted at low pH by polypurine.polypyrimidine (Pur.Pyr) inserts in plasmids. DNA samples must be preincubated in the presence of multivalent ions at 50 degrees C for the new transition to occur. At neutral pH in the presence of Co hexamine, both strands of the insert have modification maxima situated at one-third of the distance from both ends. We propose the formation of a new structure called nodule DNA which consists of both Pyr.Pur.Pyr and Pur.Pur.Pyr triplexes and does not contain continuous single-stranded regions. At basic pH (greater than 8.5) in the presence of magnesium ions, the modification pattern corresponds to Pur.Pur.Pyr triplex formation in the whole insert. At neutral pH in the presence of magnesium, both nodule DNA and the Pur.Pur.Pyr triplex can be formed in the insert. We also observed a magnesium-dependent transition at neutral pH in the other Pur.Pyr insert containing plasmids. These data demonstrate that Pur.Pyr sequences can adopt several non-B conformations at close to in vivo conditions.     

Pyrimidine morpholino oligonucleotides form a stable triple helix in the absence of magnesium ions

Oligonucleotides can be used as sequence-specific DNA ligands by forming a local triple helix. In order to form more stable triple-helical structures or prevent their degradation in cells, oligonucleotide analogues that are modified at either the backbone or base level are routinely used. Morpholino oligonucleotides appeared recently as a promising modification for antisense applications. We report here a study that indicates the possibility of a triple helix formation with a morpholino pyrimidine TFO and its comparison with a phosphodiester and a phosphoramidate oligonucleotide. At a neutral pH and in the presence of a high magnesium ion concentration (10 mM), the phosphoramidate oligomer forms the most stable triple helix, whereas in the absence of magnesium ion but at a physiological monovalent cation concentration (0.14 M) only morpholino oligonucleotides form a stable triplex. To our knowledge, this is the first report of a stable triple helix in the pyrimidine motif formed by a noncharged oligonucleotide third strand (the morpholino oligonucleotide) and a DNA duplex. We show here that the structure formed with the morpholino oligomer is a bona fide triple helix and it is destabilized by high concentrations of potassium ions or divalent cations (Mg(2+)).     

Chemical modification of triplex-forming oligonucleotide to promote pyrimidine motif triplex formation at physiological pH

Extreme instability of pyrimidine motif triplex DNA at physiological pH severely limits its use in wide variety of potential applications, such as artificial regulation of gene expression, mapping of genomic DNA, and gene-targeted mutagenesis in vivo. Stabilization of pyrimidine motif triplex at physiological pH is, therefore, crucial for improving its potential in various triplex-formation-based strategies in vivo. To this end, we investigated the effect of 3'-amino-2'-O,4'-C-methylene bridged nucleic acid modification of triplex-forming oligonucleotide (TFO), in which 2'-O and 4'-C of the sugar moiety were bridged with the methylene chain and 3'-O was replaced by 3'-NH, on pyrimidine motif triplex formation at physiological pH. The modification not only significantly increased the thermal stability of the triplex but also increased the binding constant of triplex formation about 15-fold. The increased magnitude of the binding constant was not significantly changed when the number and position of the modification in TFO changed. The consideration of the observed thermodynamic parameters suggested that the increased rigidity of the modified TFO in the free state resulting from the bridging of different positions of the sugar moiety with an alkyl chain and the increased hydration of the modified TFO in the free state caused by the introduction of polar nitrogen atoms may significantly increase the binding constant at physiological pH. The study on the TFO viability in human serum showed that the modification significantly increased the resistance of TFO against nuclease degradation. This study presents an effective approach for designing novel chemically modified TFOs with higher binding affinity of triplex formation at physiological pH and higher nuclease resistance under physiological condition, which may eventually lead to progress in various triplex-formation-based strategies in vivo.     

Effect of high magnesium ion concentration on the electron transport rate and proton exchange in thylakoid membranes in higher plants]

The effects of magnesium ion concentration on the rate of electron transport in isolated pea thylakoids were investigated in the pH range from 4.0 up to 8.0. In the absence of magnesium ions in the medium and in the presence of 5 mM MgCl2 in the experiments not only without added artificial acceptors but also with ferricyanide or methylviologen as an acceptor, this rate had a well-expressed maximum at pH 5.0. It was shown that, after depression to minimal values at pH 5.5-6.5, it gradually rose with increasing pH. An increase in magnesium ion concentration up to 20 mM essentially affected the electron transfer rate: it decreased somewhat at pH 4.0-5.0 but increased at higher pH values. At this magnesium ion concentration, the maximum rate was at pH 6.0-6.5 and the minimum, at pH 7.0. Subsequent rise upon increasing pH to 8.0 was expressed more sharply. The influence of high magnesium ion concentration on the rate of electron transport was not observed in the presence of gramicidin D. It was found that without uncoupler, the changes in the electron transfer rate under the influence of magnesium ions correlated to the changes in the first-order rate constant of the proton efflux from thylakoids. It is supposed that the change in the ability of thylakoids to keep protons by the action of magnesium ions is the result of electrostatic interactions of these ions with the charges on the external surface of membranes. A possible role of regulation of the electron transport rate by magnesium ions in vivo is discussed.     

A psoralen-conjugated triplex-forming oligodeoxyribonucleotide containing alternating methylphosphonate-phosphodiester linkages: synthesis and interactions with DNA.

A psoralen-conjugated oligodeoxyribopyrimidine (1443), PS-pTTTTCTTTTCTTCTT, where PS is trimethylpsoralen and C is 5-methyl-2'-deoxycytidine, that contains alternating methylphosphonate-phosphodiester internucleotide linkages was synthesized. The ability of 1443 to form triple-stranded complexes with a purine tract in a synthetic DNA duplex was studied. Irradiation of solutions containing the DNA target and 10 microM 1443 or 0.25 microM of a similar psoralen-conjugated oligodeoxyribonucleotide that contained all phosphodiester linkages, (1193), with long-wavelength UV light resulted in approximately 80% formation of interstrand cross-links at pH 7.0, 37 degrees C, in the presence of 20 mM magnesium chloride. The extent of triplex formation as monitored by photo-cross-linking decreased over the pH range 5.5-8.0, and the apparent pK of the 5-methylcytosines (C) in 1443 was approximately one-half of a pH unit less than that of the 5-methylcytosines in 1193. Oligomer 1443 formed triplexes in the absence of magnesium, and maximum triplex formation was observed in solutions containing 2.5 mM magnesium, whereas maximal triplex formation by the fully charged 1193 was not observed until the magnesium concentration was 10 mM or higher. Unlike the all-phosphodiester backbone of 1193, the alternating methylphosphonate-phosphodiester backbone of 1193 is resistant to hydrolysis by exonucleases in fetal calf serum. The nuclease resistance of 1443 and its ability to form triplexes at very low magnesium concentrations suggests that triplex-forming oligomers with alternating methylphosphonate-phosphodiester backbones may be good candidates for use as antigene reagents in cell culture.     

Formation of magnesium-phosphoenzyme and magnesium-calcium-phosphoenzyme in the phosphorylation of adenosine triphosphatase by orthophosphate in sarcoplasmic reticulum. Models of a reaction sequence

The aim of the present study was to test simple reaction sequences which describe calcium-independent plus calcium-dependent phosphorylation of sarcoplasmic reticulum transport. ATPase by orthophosphate including the function of magnesium in phosphoenzyme formation. The reaction schemes considered were based on the reaction sequence for calcium-independent phosphorylation proposed previously; namely that the transport enzyme (E) forms a ternary complex (Mg . E . Pi), by random binding of free magnesium and free orthophosphate, which is in equilibrium with the magnesium-phosphoenzyme (Mg . E-P). Phosphorylation, performed at pH 7.0 20 degrees C and a constant free orthophosphate concentration using sarcoplasmic reticulum vesicles either unloaded or loaded passively with calcium in the presence of 5 mM or 40 mM CaCl2, resulted in a gradual decrease in the apparent magnesium half-saturation constant and an increase in maximum phosphoprotein formation with increasing calcium loads. When phosphorylation of sarcoplasmic reticulum vesicles preloaded in the presence of 5 mM CaCl2 was performed at a constant free magnesium concentration, a decrease in the apparent orthophosphate half-saturation constant and an increase in maximum phosphoprotein formation was observed as compared with vesicles from which calcium inside has been removed by ionophore X-537A plus EGTA treatment; however, both parameters remained unchanged by increasing free magnesium from 20 mM to 30 mM. When phosphorylation of sarcoplasmic reticulum vesicles passively loaded with calcium in the presence of 40 mM CaCl2, at which the saturation of the low-affinity calcium binding sites of the ATPase is presumably near maximum, was performed at increasing concentrations of free orthophosphate, there was a parallel shift of phosphoprotein formation as a function of free magnesium and vice versa, with no change in the maximum phosphoenzyme formation. Comparison of the experimental data with the pattern of phosphoprotein formation predicted from model equations for various theoretical possible reaction sequences suggests that phosphoenzyme formation from orthophosphate possesses the following features. Firstly, calcium present at the inside of the sarcoplasmic reticulum membrane binds to the free enzyme and in sequential order to E . Mg . Pi or Mg . E-P or to both, but neither to E. Mg nor to E . Pi. Secondly, calcium-independent and calcium-dependent phosphoproteins are magnesium-phosphoenzymes. Calcium-dependent phosphoenzyme is a magnesium-calcium-enzyme phosphate complex with 1 magnesium, 2 calciums and 1 orthophosphate (the last covalently) bound to the enzyme [Mg . E-P . (Cai)2], and not a 'calcium-phosphoprotein' without bound magnesium.     

Cationic oligonucleotides can mediate specific inhibition of gene expression in Xenopus oocytes.

Base-specific hydrogen bonding between an oligonucleotide and the purines in the major groove of a DNA duplex provide an approach to selective inhibition of gene expression. Oligonucleotide-mediated triplex formation in vivo may be enhanced by a number of different chemical modifications. We have previously described an in vitro analysis of triplex formation using oligonucleotides containing internucleoside phosphate linkages modified with the cation N , N -diethyl-ethylenediamine (DEED). When compared with unmodified oligonucleotides of identical base composition, DEED-modified oligonucleotides were better able to form DNA triplexes under conditions that approximate the pH, magnesium and potassium levels found in vivo . Here we report the ability of DEED-modified oligonucleotides to inhibit the expression of plasmid DNA injected into Xenopus oocytes. Inhibition is specific to plasmids containing a triplex formation target and sensitive to sequence alteration in the triplex forming target site. Inhibition of gene expression was nearly complete when oligonucleotide and plasmid were mixed together prior to injection. Inhibition was partial when oligonucleotide was injected first and not evident when plasmid was injected and allowed to form chromatin prior to oligonucleotide injection. Thus, access to DNA is a determining factor in effective triplex inhibition of gene expression.     

Binding of triple helix forming oligonucleotides to sites in gene promoters

A class of triplex-forming oligodeoxyribonucleotides (TFOs) is described that can bind to naturally occurring sites in duplex DNA at physiological pH in the presence of magnesium. The data are consistent with a structure in which the TFO binds in the major groove of double-stranded DNA to form a three-stranded complex that is superficially similar to previously described triplexes. The distinguishing features of this class of triplex are that TFO binding apparently involves the formation of hydrogen-bonded G.GC and T.AT triplets and the TFO is bound antiparallel with respect to the more purine-rich strand of the underlying duplex. Triplex formation is described for targets in the promoter regions of three different genes: the human c-myc and epidermal growth factor receptor genes and the mouse insulin receptor gene. All three sites are relatively GC rich and have a high percentage of purine residues on one strand. DNase I footprinting shows that individual TFOs bind selectively to their target sites at pH 7.4-7.8 in the presence of millimolar concentrations of magnesium. Electrophoretic analysis of triplex formation indicates that specific TFOs bind to their target sites with apparent dissociation constants in the 10(-7)-10(-9) M range. Strand orientation of the bound TFOs was confirmed by attaching eosin or an iron-chelating group to one end of the TFO and monitoring the pattern of damage to the bound duplex DNA. Possible hydrogen-bonding patterns and triplex structures are discussed.