Syntheses of [12]aneN₃-oligopeptide conjugates as effective DNA condensation agents

With the aim to develop effective and low toxicity DNA condensation agents, a series of oligopeptide derived macrocyclic polyamine [12]aneN(3) conjugates 7a-h·3HCl have been designed and synthesized through multi-step amidation reactions. Structure-property study through gel electrophoresis proved that the conjugates containing high hydrophobic ending amino acids exhibited effective condensation ability at concentration of 150-250 μM, which was further confirmed by dynamic light scattering and atomic force microscopy experiments. EB displacement assay, ionic salt effect, and structure-property relationship in gel electrophoresis indicated that DNA condensation resulted from both the electrostatic interaction of [12]aneN(3) unit and hydrogen-bonding/hydrophobic multi-interaction of oligopeptide moiety in the conjugates with DNA. The reversible condensation process and their low cytotoxicity suggest that the new condensing agents are potential for the development of non-viral vectors.     

Sulfomethylation of Di-, Tri-, and polyazamacrocycles: a new route to entry of mixed-side-chain macrocyclic chelates.

The sulfomethylation of piperazine and the polyazamacrocycles, [9]aneN3, [12]aneN3, [12]aneN4, and [18]aneN6 with formaldehyde bisulfite in aqueous medium at various pH values is described. The number of methanesulfonate groups introduced into these structures was found to be largely determined by pH. At neutral pH, disubstituted products of [9]aneN3, [12]aneN3, [12]aneN4 are formed and, in the latter case, the trans-1,7-bis(methanesulfonate) isomer was predominant. Similarly, a single, symmetrical trisubstituted product was formed with [18]aneN6 at neutral pH. Monomethanesulfonated products of these same polyaza compounds were formed at more acidic pH's. These sulfomethylated products were used as an entry into a series of mono- and diacetate, phosphonate, and phosphinate derivatives of [9]aneN3, [12]aneN3, and [12]aneN4. The sulfonate groups may be converted to acetates without isolation of intermediates by using cyanide to displace the sulfonate(s) followed by acidic hydrolysis. The aminomethanesulfonates may also be oxidatively hydrolyzed by using aqueous triiodide as a prelude to the preparation of aminomethanephosphonates or aminomethanephosphinates.     

Effect of a conjugated acridine moiety on the binding and reactivity of Cu(II)[9-acridinylmethyl-1,4,7-triazacyclononane] with DNA

The DNA binding orientation and dynamic behavior of Cu(II) complexes of 1,4,7-triazacyclononane ([9]aneN(3)), 1, and an acridine conjugate, 2, were investigated by DNA fiber EPR (EPR=electron paramagnetic resonance) spectroscopy. Crystal and molecular structure of 2 were determined by X-ray diffraction. It has been shown that 1 binds to DNA in two different modes at room temperature; one species is rapidly rotating and the other is immobilized randomly on the DNA. The introduction of acridine to [9]aneN(3) fixed the [Cu([9]aneN(3))](2+) moiety of 2 in two different environments on the DNA: the g(mid R:mid R:) axis of one species (g( parallel)=2.26) is aligned perpendicularly to the DNA fiber axis whereas that of the other (g( parallel)=2.24) aligns<90 degrees with the DNA fiber axis. The different DNA binding structures of 1 and 2 are reflected also in their different efficiencies of DNA cleavage; 2 was found to be more effective both in oxidative and hydrolytic cleavage reactions.     

Both strands of polyoma DNA are replicated discontinuously with ribonucleotide primers in vivo

Nascent polyoma DNA molecules were isolated after pulse-labeling of infected murine 3T6 cells with [3H]thymidine. The extent of digestion of these DNA molecules by spleen exonuclease was increased by exposure to alkali or RNase, suggesting that ribonucleotides were present at or near the 5' terminal of the newly synthesized pieces of DNA. Intermediates shorter than 300 nucleotides were hybridized to the separated strands of restriction enzyme fragments of the polyoma genome: 2.5 to 3-fold more radioactivity was found in the strand whose synthesis is necessarily discontinuous (the lagging strand) than in the strand whose synthesis is potentially continuous (the leading strand) than in the strand whose synthesis is potentially continuous (the leading strand). Separation of the strands of [5'-32P]DNA molecules showed that the excess [3H]thymidine in lagging-strand molecules was not simply the result of an increased number of molecules. Therefore, assuming equivalent efficiencies of labeling, lagging-strand pieces must be slightly longer than those with leading-strand polarity. The presence of ribonucleotides on the 5' termini of molecules with both leading- and lagging-strand polarity was demonstrated by (i) release of 32P-ribonucleoside diphosphates upon alkaline hydrolysis of [5'-32P]DNA separated according to replication polarity and (ii) the change in the degree of self-annealing of nascent molecules upon preferential degradation of DNA molecules possessing initiator RNA moieties by spleen exonuclease. We conclude that replication of polyoma DNA in vivo occurs discontinuously on both sides of the growing fork, using RNA as the major priming mechanism.     

Origin of rate-acceleration in ester hydrolysis with metalloprotease mimics

Mimics of carboxypeptidase A, a prototypical metalloprotease, were synthesized by linking macrocyclicpolyamines to the primary side of beta-cyclodextrin followed by complexing with Zn(II). These enzyme mimics exhibit saturation kinetics in hydrolysis of p-nitrophenyl acetate (PNPA) and enhance the rate of hydrolysis reaction by almost 300-fold. The effective molarities (EM) of the mimics range from 0.2 to 1.9 M. Origin of the rate acceleration was examined: the reactivity of Zn(II) complexes of [12]aneN3 [12]aneN4, and [14]aneN4 for hydrolyzing PNPA increases with increase in basicity of the zinc bound hydroxides [Zn(II)-OH], yielding a linear Br?nsted plot. Free hydroxide fits well on this plot. A similar plot was obtained with the enzyme mimics. The Br?nsted relationships indicate that the Zn(II)-OH in the catalytic systems hydrolyzes the ester by direct nucleophilic attack on the ester carbonyl of cyclodextrin-bound but not Zn(II)-coordinated PNPA.     

Apoptotic nuclear morphological change without DNA fragmentation.

Apoptosis is characterized morphologically by condensation and fragmentation of nuclei and cells and biochemically by fragmentation of chromosomal DNA into nucleosomal units [1]. CAD, also known as CPAN or DFF-40, is a DNase that can be activated by caspases [2] [3] [4] [5] [6]. CAD is complexed with its inhibitor, ICAD, in growing, non-apoptotic cells [2] [7]. Caspases that are activated by apoptotic stimuli [8] cleave ICAD. CAD, thus released from ICAD, digests chromosomal DNA into nucleosomal units [2] [3]. Here, we examine whether nuclear morphological changes induced by apoptotic stimuli are caused by the degradation of chromosomal DNA. Human T-cell lymphoma Jurkat cells, as well as their transformants expressing caspase-resistant ICAD, were treated with staurosporine. The chromosomal DNA in Jurkat cells underwent fragmentation into nucleosomal units, which was preceded by large-scale chromatin fragmentation (50-200 kb). The chromosomal DNA in cells expressing caspase-resistant ICAD remained intact after treatment with staurosporine but their chromatin condensed as found in parental Jurkat cells. These results indicate that large-scale chromatin fragmentation and nucleosomal DNA fragmentation are caused by an ICAD-inhibitable DNase, most probably CAD, whereas chromatin condensation during apoptosis is controlled, at least in part, independently from the degradation of chromosomal DNA.     

Synthesis of [12]aneN3-dipeptide conjugates as metal-free DNA nucleases

In this Letter, a series of macrocyclic polyamine [12]aneN(3)-dipeptide conjugates as a new type of metal-free nucleases were synthesized and fully characterized with (1)H NMR, (13)C NMR, IR, and HR-MS. Results indicate that these conjugates can bind to calf thymus DNA mainly through electrostatic interaction and can cleave the plasmid DNA at 200 μM (pH 7.2, 37°C), with an acceleration of 10(6)-fold via hydrolytic pathway.     

First generation TREN dendrimers functionalized with naphthyl and/or dansyl units. Ground and excited state electronic interactions and protonation effects.

We report the photophysical properties (absorption and emission spectra, quantum yield, and lifetime) of five dendrimers of first generation based on a TREN (tris(2-aminoethyl)amine) skeleton functionalized at the periphery with naphthyl and/or 5-dimethylamino-1-naphthalenesulfonamide (hereafter called dansyl) chromophores. Each dendrimer comprises one tertiary amine unit in the core and three branches carrying a sulfonimido unit at the periphery, each one substituted by two identical or different moieties. In particular, TD6 and TN6 contain dansyl (D) or naphthyl (N) units, respectively, while TD3B3, TN3B3 and TN3D3 contain dansyl, naphthyl or benzyl (B) units at the periphery. The spectroscopic behaviour of these dendrimers has been investigated in acetonitrile solution and compared with that of reference compounds. For all dendrimers the absorption bands are red shifted compared to those of monomeric naphthyl and dansyl reference compounds. Moreover, the intense naphthyl and dansyl fluorescence is greatly quenched because of strong interactions between the two aromatic moieties linked by a sulfonimido unit. Protonation of the amine units of the dendrimers by addition of CF(3)SO(3)H (triflic) acid causes a decrease in intensity of the luminescence and a change in the shape of the emission bands. The shapes of the titration curves depend on the dendrimer, but in any case the effect of acid can be fully reversed by successive addition of base (tributylamine). The obtained results reveal that among the intradendrimer interactions the most important one is that taking place (via mesomeric interaction) between the various chromophores and a pair of sulfonimido groups.     

Metal ion-dependent hydrolysis of RNA phosphodiester bonds within hairpin loops. A comparative kinetic study on chimeric ribo/2'-O-methylribo oligonucleotides.

Several chimeric ribo/2'- O -methylribo oligonucleotides were synthesized and their hydrolytic cleavage studied in the presence of Mg2+, Zn2+, Pb2+and the 1,4,9-triaza-cyclododecane chelate of Zn2+(Zn2+[12]aneN3) to evaluate the importance of RNA secondary structure as a factor determining the reactivity of phosphodiester bonds. In all the cases studied, a phosphodiester bond within a 4-7 nt loop was hydrolytically more stable than a similar bond within a linear single strand, but markedly less stable than that in a double helix. With Zn2+and Zn2+[12]aneN3, the hydrolytic stability of a phosphodiester bond within a hairpin loop gradually decreased on increasing the distance from the stem. A similar but less systematic trend was observed with Pb2+. Zn2+- and Pb2+-promoted cleavage was observed to be considerably more sensitive to the secondary structure of the chain than that induced by Zn2+[12]aneN3. This difference in behaviour may be attributed to bidentate binding of uncomplexed aquo ions to two different phosphodiester bonds. Mg2+was observed to be catalytically virtually inactive compared with the other cleaving agents studied.     

Characterization of the mechanisms of action and nitric oxide species involved in the relaxation induced by the ruthenium complex

Nitric oxide (NO) plays an important role in the control of vascular tone. NO donors have therapeutic use and the most used NO donors, nitroglycerin and sodium nitroprusside have problems in their use. Thus, new NO donors have been synthesized to minimize these undesirable effects. Nytrosil ruthenium complexes have been studied as a new class of NO donors. trans-[RuCl([15]aneN(4))NO](2+), induces vasorelaxation only in presence of reducing agent. In this study, we characterized the mechanisms of vasorelaxation of trans-[RuCl([15]aneN(4))NO](2+) in denuded rat aorta and identified which NO forms are involved in this relaxation. We also evaluated the effect of this NO donor in decreasing the cytosolic Ca(2+) concentration ([Ca(2+)]c) of the vascular smooth muscle cells. Vasorelaxation to trans-[RuCl([15]aneN(4))NO](2+) (E(max): 101.8 +/- 2.3%, pEC(50): 5.03 +/- 0.15) was almost abolished in the presence of the NO* scavenger hydroxocobalamin (E(max): 4.0 +/- 0.4%; P < 0.001) and it was partially inhibited by the NO(-) scavenger L-cysteine (E(max): 79.9 +/- 6.9%, pEC(50): 4.41 +/- 0.06; P < 0.05). The guanylyl cyclase inhibitor ODQ reduced the E(max) (57.7 +/- 4.0%, P < 0.001) and pEC(50) (4.21 +/- 0.42, P < 0.01) and the combination of ODQ and TEA abolished the response to trans-[RuCl([15]aneN(4))NO](2+). The blockade of voltage-dependent (K(v)), ATP-sensitive (K(ATP)), and Ca(2+)-activated (K(Ca) K(+) channels reduced the vasorelaxation induced by trans-[RuCl([15]aneN(4))NO](2+). This compound significantly reduced [Ca(2+)]c (from 100% to 85.9 +/- 3.5%, n = 4). In conclusion, our data demonstrate that this NO donor induces vascular relaxation involving NO* and NO(-) species, that is associated to a decrease in [Ca(2+)]c. The mechanisms of vasorelaxation involve guanylyl cyclase activation, cGMP production and K(+) channels activation.     

Condensation of DNA by multivalent cations: experimental studies of condensation kinetics

DNA in viruses and cells exists in highly condensed, tightly packaged states. We have undertaken an in vitro study of the kinetics of DNA condensation by the trivalent cation hexaammine cobalt (III) with the aim of formulating a quantitative, mechanistic model of the condensation process. Experimental approaches included total intensity and dynamic light scattering, electron microscopy, and differential sedimentation. We determined the average degree of condensation, the distribution of condensate sizes, and the fraction of uncondensed DNA as a function of reaction time for a range of [DNA] and [Co(NH(3))(3+)(6)]. We find the following: (1) DNA condensation occurs only above a critical [Co(NH(3))(3+)(6)] for a given DNA and salt concentration. At the onset of condensation, [Co(NH(3))(3+)(6)]/[DNA-phosphate] is close to the average value of 0.54, which reflects the 89-90% charge neutralization criterion for condensation. (2) The equilibrium weight average hydrodynamic radius of the condensates first decreases, then increases with increasing [Co(NH(3))(3+)(6)] as they undergo a transition from intramolecular (monomolecular) to intermolecular (multimolecular) condensation. However, is insensitive to [DNA]. (3) The uncondensed DNA fraction decays approximately exponentially with time. The equilibrium uncondensed DNA fraction and relaxation time decrease with increasing [Co(NH(3))(3+)(6)] but are insensitive to [DNA]. (4) The condensation rate in its early stages is insensitive to [DNA] but proportional to [Co(NH(3))(3+)(6)](xs) = [Co(NH(3))(3+)(6)] - [Co(NH(3))(3+)(6)](crit). (5) Data for low [DNA] and low [Co(NH(3))(3+)(6)] at early stages of condensation are most reliable for kinetic modeling since under these conditions there is minimal clumping and network formation among separate condensates. A mechanism with initial monomolecular nucleation and subsequent bimolecular association and unimolecular dissociation steps with rate constants that depend on the number of DNA molecules in the condensate, accounts reasonably well for these observations.     

Hepatic glucocorticoid receptor behaves differently when its hormone binding site is occupied by agonist (triamcinolone acetonide) or antagonist (RU486) steroid ligands

We have examined the influence of sulfhydryl (SH)-group modifying agents on the interaction of the rat liver glucocorticoid receptor (GR) with its known agonist triamcinolone acetonide (TA) and the newly synthesized antagonist mifepristone (RU486). In the freshly prepared cytosol, [3H]TA or [3H]RU486 bound to macromolecule(s) which sediment as 8-9 moieties: the binding of either ligand can be competed with radioinert TA or RU486. The presence of 2-10 mM dithiothreitol (DTT), beta-mercaptoethanol (beta-MER), and monothioglycerol (MTG) caused a 2-3 fold increase in the [3H]TA and [3H]RU486 binding to GR. Iodoacetamide (IA) and N-ethylmaleimide (NEM) decreased the agonist binding significantly. In contrast, the [3H]RU486 binding to GR increased by 50 percent in the presence of IA. IA and NEM inhibited the binding of the heat-transformed [3H]TA-receptor complex to DNA-cellulose by 70-90 percent whereas DNA binding of [3H]RU486-bound GR was inhibited only slightly. These results indicate that either a) the interaction of GR with the agonist or antagonist steroid ligands causes differential structural alterations, which are more readily detectable in the presence of SH-modifying agents or b) the agonist and the antagonist interact with distinct steroid binding sites.     

The macrocyclic effect and vasodilation response based on the photoinduced nitric oxide release from trans-[RuCl(tetraazamacrocycle)NO](2+)

Irradiation of trans-[RuCl(cyclam)(NO)](2+), cyclam is 1,4,8,11-tetraazacyclotetradecane, at pHs 1-7.4, with near UV light results in the release of NO and formation of trans-[Ru(III)Cl(OH)(cyclam)](+) with pH dependent quantum yields (from approximately 0.01 to 0.16 mol Einstein(-1)) lower than that for trans-[RuCl([15]aneN(4))(NO)](2+), [15]aneN(4) is 1,4,8,12-tetaazacyclopentadecane, (0.61 mol Einstein(-1)). After irradiation with 355 nm light, the trans-[RuCl([15]aneN(4))(NO)](2+) induces relaxation of the aortic ring, whereas the trans-[RuCl(cyclam)(NO)](2+) complex does not. The relaxation observed with trans-[RuCl([15]aneN(4))(NO)](2+) is consistent with a larger quantum yield of release of NO from this complex.     

Calditol tetraether lipids of the archaebacterium Sulfolobus solfataricus. Biosynthetic studies.

Lipids from the archaebacterium Sulfolobus solfataricus are based on 72-membered macrocyclic tetraethers made up from two C40 diol units differently cyclized and either two glycerol moieties or one glycerol moiety and a unique branched-chain nonitol named calditol (glycerodialkylnonitol tetraethers, GDNTs). To elucidate the biosynthesis of calditol and related tetraethers, labelled precursors, [U-14C,1(3)-3H]glycerol, [U-14C,2-3H]glycerol, D-[1-14C,6-3H]glucose, D-[6-14C,1-3H]glucose, D-[1-14C,2-3H]glucose, D-[1-14C,6-3H]fructose and D-[1-14C]galactose, were fed to S. solfataricus. Without regard to stereochemistry or phosphorylation, incorporation experiments provided evidence that the biosynthesis of calditol occurs via an aldolic condensation between dihydroxyacetone and fructose, through a 2-oxo derivative of calditol as an intermediate. The latter is in turn reduced and then alkylated to yield the GDNTs. The biogenetic origins of both glycerol and C40 isoprenoid moieties of GDNTs are also discussed.     

Tryptophan 2,3-dioxygenase: a review of the roles of the heme and copper cofactors in catalysis.

L-Tryptophan, 2,3-dioxygenase (EC 1.13.11.11) has been purified to homogenity from L-tryptophan induced Pseudomonas acidovorans (ATCC 11299b) and from L-tryptophan and cortisone induced rat liver. The enzyme from both sources is composed of four subunits and contains two g-atoms copper and two moles heme per mole tetramer. The proteins from the two sources are not identical. Three oxidation states of tryptophan oxygenase have been isolated: (1) fully oxidized, [Cu(II)]2[Ferriheme]2; (2) half reduced, [Cu(i)]2[ferriheme]2; and (3) fully reduced, [Cu(I)]2[ferroheme]2. Catalytic activity is dependent solely on the presence of Cu(I) in the enzyme, the heme may be either ferro or ferri. The presence of Cu(II) in the enzyme results in a requirement for an exogenous reductant, such as ascorbate, in order to elicit enzymic activity. Ligands, such as cyanide and carbon monoxide, can inhibit catalysis by binding to either or to both the copper and heme moieties. Metal complexing agents, such as bathocuproinesulfonate and bathophenanthrolinesulfonate, can inhibit catalysis by binding to Cu(I) resent only in catalytically active enzyme molecules. During catalysis by the fully reduced form of the enzyme, molecular oxygen binds to the heme moieties, while during catalysis by the half reduced form of the enzyme it does not, presumably binding instead to the Cu(I) moieties. Enzymes that catalyze similar reactions have been purified from other sources. Indoleamine 2,3-dioxygenase appears to be a heme protein, but its copper content is unknown. Pyrrolooxygenases appear to be completely different enzymes, although they have not yet been purified to homegeneity.     

In vitro synthesis of simian virus 40 DNA. II. Evidence for a repair mechanism.

The technique of density labeling of DNA by BrdU was used to characterize the material synthesized in vitro by cytoplasmic extracts of SV40 infected cells incubated in the presence of simian virus 40 (SV40) DNA component I molecules (Girard et al, Biochimie, this volume). In a first experiment, the template was labeled beforehand in vivo using [14C]-BrdU, and the in vitro incubation was carried out in the presence of [3H]-dGTP and [3H]-dTTP. In a second experiment, the template was labeled in vivo with 32P, and the in vitro incubation was in the presence of [3H]-dGTP and BrdUTP. After digestion with the restriction endonuclease Hind II + III, the fragments from the end products of the reaction were analyzed by density gradient centrifugation, at pH 7 and pH 13. In both experiments the DNA product molecules had the same density as the resepctive DNA templates. Cellular enzymes seem to be responsible for this in vitro synthesis of DNA, since cytoplasmic extracts from uninfected cells were almost as active as those from SV40 infected cells. The system was proved efficient in the conversion of "open circular" molecules (component II DNA molecules) to covalently closed circular DNA molecules (relaxed component I molecules). The use of DNA complexed with histones did not impart viral specificity to the system. It is concluded that the cytoplasmic extract is only capable of supporting the repair synthesis of added viral DNA.     

DNA cleavage by novel copper (II) complex and the role of beta-cyclodextrin in promoting cleavage

A new cyclen derivative N-1-naphthyl-[4-amino-5-oxo-5-(1,4,7,10-tetraazacyclododecan-1-yl)]valeramide and the copper (II) complex were synthesized and characterized. The copper (II) complex showed DNA cleavage ability without the existence of other additives. The pUC19 plasmid DNA was cleaved to linear form by 0.71 microM of complex under physiological conditions. beta-Cyclodextrin was used to investigate the relationship of nuclease activity and DNA binding ability. The addition of beta-cyclodextrin exhibited an unexpected ability to promote the cleavage of DNA. The role of the beta-cyclodextrin in DNA cleavage process was studied by (1)H NMR and fluorescence spectrum. According to the data of viscosity measurement, it was confirmed that the binding of complex with DNA should be a groove binding model. All the results suggested that the increasing of the DNA cleavage ability was attributed to the interaction between beta-cyclodextrin and the naphthyl moieties. beta-Cyclodextrin could include the naphthyl moieties and keep it from the minor/major groove of DNA and decreased the DNA binding ability, therefore, the copper (II) center was activated to generate more reactive oxygen species, which was responsible for DNA cleavage.     

Asymmetric distribution of exogenous thymidine among pyrimidine isostichs suggests compartmentalization of replicative DNA synthesis during regeneration in rat liver

The distribution of radioactivity among pyrimidine isostichs (or isoplyths) of DNA from 24-h regenerating rat liver was studied with [3H]Thd, [14C]orotate or with inorganic 32Pi. Expression of incorporated radioactivity as log10% of total radioactivity recovered for each of the 11 pyrimidine isostichs detected showed that radioactivity from [3H]Thd was asymmetrically distributed among the isostichs, i.e., 3H radioactivity failed to access regions of DNA yielding lower molecular weight pyrimidine isostichs as efficiently as it accessed regions yielding higher molecular weight pyrimidine isostichs. The thymine (T) content of isostichs exceeded that of cytosine (C), i.e., T/C ratios for the first 10 isostichs averaged 1.43 +/- 0.08 and 1.28 +/- 0.05, depending on the method of analysis; furthermore, the T/C ratio for isostich 1 was significantly higher than ratios for isostichs 2 through 10. Asymmetric distributions of [3H]Thd radioactivity also were seen at 18 or 30 h post-partial hepatectomy. Thus, radioactivity from [3H]Thd, a DNA precursor from the salvage pathway, failed to efficiently access lower molecular weight isostichs despite thymine enrichment, suggesting that thymine moieties were supplied from additional sources. Radioactivity from [14C]orotate accessed lower molecular weight pyrimidine tracts more efficiently than [3H]Thd, but less efficiently than it accessed higher molecular weight isostichs, resulting in an asymmetric distribution of 14C radioactivity. This result suggested that appreciable quantities of thymine and cytosine moieties utilized for DNA synthesis were supplied de novo, but other sources also were utilized. Radioactivity from 32Pi, a de novo precursor, was distributed symmetrically, i.e., the slope among lower molecular weight isostichs increased enough that it was indistinguishable from slopes for intermediate and higher molecular weight isostichs. Since 32P radioactivity among lower molecular weight isostichs reflects appreciable contributions of de novo phosphate moieties from both pyrimidine- and purine-containing deoxynucleoside triphosphates, opportunities for observing contributions of 32P radioactivity from pathways other than the de novo pathways appeared to lie beyond limits of detectability. The distribution of radioactivity from labeled DNA precursors among lower molecular weight pyrimidine tracts (a) indicate that thymine moieties are contributed by both salvage and de novo pathways; (b) support the possibility that cytosine moieties also are contributed by both pathways; and (c) support the 'replitase' concept for channeling dNTPs to replicating forks.     

Structure and dynamics of condensed DNA probed by 1,1'-(4,4,8,8-tetramethyl-4,8-diazaundecamethylene)bis[4-[[3- methylbenz-1,3-oxazol-2-yl]methylidine]-1,4-dihydroquinolinium] tetraiodide fluorescence

Information on the structure and dynamics of condensed forms of DNA is important in understanding both natural situations such as DNA packaging and artificial systems such as gene delivery complexes. We have established the fluorescence of bisintercalator 1,1'-(4,4,8,8-tetramethyl-4,8-diazaundecamethylene)bis[4-[[3-methylbenz-1,3-oxazol-2-yl]methylidine]-1,4-dihydroquinolinium] tetraiodide (YOYO-1) as a novel probe for DNA condensation. When the level of DNA-bound YOYO-1 is sufficiently large, condensation by either polyethylenimine (PEI) or the cationic detergent cetyltrimethylammonium bromide (CTAB) leads to electronic interaction among YOYO-1 molecules bound on the same DNA molecule. This interaction results in an excitonic blue shift of the absorption spectra of YOYO-1 and dramatic decrease in the fluorescence quantum yield. These observations constitute a signature of the condensation of DNA. We further examined the comparative properties of DNA condensed by PEI, CTAB, or Co(NH(3))(6)(3+) through the steady-state and dynamic fluorescence of YOYO-1. Condensation by either PEI or CTAB was associated with a blue shift in the absorption spectra of YOYO-1, although the magnitude of the shift was larger in the case of PEI when compared to that of CTAB. In contrast, condensation by Co(NH(3))(6)(3+) was not associated with a measurable shift in the absorption spectra. These results were interpreted as signifying the varying level of compactness of the DNA condensates. Quenching of fluorescence by acrylamide showed that condensation by all three agents led to an increase in the level of solvent exposure of the base pairs. Observation of the decay of fluorescence intensity and anisotropy of DNA-bound YOYO-1 showed that while condensation by either PEI or CTAB froze the segmental mobility of the helix, condensation by Co(NH(3))(6)(3+) enhanced the flexibility of DNA. The relevance of our findings to functions such as efficiency of gene delivery is discussed.