Interaction of Hoechst 33258 with repeating synthetic DNA polymers and natural DNA

Fluorescence, circular dichroism and sedimentation through cesium chloride gradient techniques were performed to study the physical properties of the binding of the bisbenzimidazole dye Hoechst 33258 (H33258) to natural DNAs and synthetic polynucleotides of defined repeating units. These studies show that Hoechst 33258 exhibits at least two modes of interaction with duplex DNA: (1) a strong base pair specific mode which requires at least 4 consecutive AT base pairs and (2) a weaker mode of binding which is significantly reduced in the presence of high salt (0.4 M NaCl) and exhibits no apparent base specificity. The H33258 binding was found to be sensitive to the substitutions in the minor groove elements of a series of synthetic polynucleotides supporting the model of H33258 binding in the minor groove of the DNA with AT rich sequences. Similar mode of binding was predicted in natural DNAs by methylation of dye-DNA complexes. Footprint analysis of the complex of dye to a pBR322 fragment also supports that a minimum of 4 consecutive AT base pairs are required for H33258 binding to DNA.     

Fluorescence studies of the interaction of DNA with Hoechst 33258

Absorption and fluorescence measurements of DNA-Hoechst 33258 complexes at high molar ratio of DNA phosphate to dye are consistent with the existence of two types of bound species. One type (Type I) predominates at high ionic strength, whereas the other (Type II) occurs at low ionic strength. The fluorescence peak (lambda fmax) depends on the excitation wavelength (lambda ex); lambda fmax shifts toward longer wavelength with increasing lambda ex. Optical properties obtained are summarized in the following: for Type I, lambda amax (absorption) = 352 nm, lambda fmax at lambda ex of 335 nm = 460 nm, tau (fluorescence lifetime) = 2.0-2.5 ns; for Type II, lambda amax = 360 nm, lambda fmax at lambda ex of 335 nm = 470 nm, tau = 4.0-5.0 ns. This behavior is interpreted in terms of solvent-solute relaxation. Type I corresponds to less hydrated bound species, while Type II to more hydrated bound species.     

Hydration changes in the association of Hoechst 33258 with DNA

The role of water in the interaction of Hoechst 33258 with the minor groove binding site of the (AATT)2 sequence was investigated using calorimetric and equilibrium constant measurements. Using isothermal titration calorimetry measurements, the heat capacity change for the reaction is -256 +/- 10 cal/(K mol of Hoechst). Comparison with the heat capacity changes based on area models supports the expulsion of water from the interface of the Hoechst-DNA complex. To further consider the role of water, the osmotic stress method was used to determine if the Hoechst association with DNA was coupled with hydration changes. Using four osmolytes with varying molecular weights and chemical properties, the Hoechst affinity for DNA decreases with increasing osmolyte concentration. From the dependence of the equilibrium constant on the solution osmolality, 60 +/- 13 waters are acquired in the complex relative to the reactants. It is proposed that the osmotic stress technique is measuring weakly bound waters that are not measured via the heat capacity changes.     

Interaction of Hoechst 33258 and echinomycin with nucleosomal DNA fragments containing isolated ligand binding sites

We have examined the interaction of Hoechst 33258 and echinomycin with nucleosomal DNA fragments which contain isolated ligand binding sites. A 145 base pair fragment was prepared on the basis of the sequence of tyrT DNA, which contained no CpG or (A/T)(4) binding sites for these ligands. Isolated binding sites were introduced into this fragment at discrete locations where the minor groove is known to face toward or away from the protein core when reconstituted onto nucleosome core particles. The interaction of ligands with target sites on these nucleosomal DNA fragments was assessed by DNase I footprinting. We find that Hoechst 33258 can bind to single nucleosomal sites which face both toward and away from the protein core, without affecting the nucleosome structure. Hoechst binding is also observed on nucleosomal fragments which contain two or more drug binding sites, though in these cases the footprints are accompanied by the presence of new cleavage products in positions which suggest that the ligand has caused a proportion of the DNA molecules to adopt a new rotational positioning on the protein surface. Hoechst 33258 does not affect nucleosome reconstitution with any of these fragments. In contrast, the bifunctional intercalating antibiotic echinomycin is not able to bind to single nucleosomal CpG sites. Echinomycin footprints are observed on nucleosomal fragments containing two or more CpG sites, but there are no changes in the cleavage patterns in the remainder of the fragment. Echinomycin abolishes nucleosome reconstitution when included in the reconstitution mixture.     

Interaction of Hoechst 33258 and ethidium with histone1-DNA condensates

We report structural and dynamical aspects of DNAs from various sources including synthetic oligonucleotides in bulk buffer and as a complex with histone1 (H1). High-resolution transmission electron microscopic (HRTEM) studies reveal the structural change of the DNAs upon complexation with H1 leading to formation of compact-globular and hollow-toroidal particles. In order to explore the functionality of ligand binding of the DNAs and their complexes with H1, we have used two biologically common fluorescent probes Hoechst 33258 (H33258) and Ethidium (EB) as model ligands. Picosecond resolved fluorescence and polarization gated anisotropy studies examined that the minor groove binding of H33258 to the genomic DNA-H1 complex remains almost unaltered. However, the intercalative interaction of EB with the DNA in the complex is severely perturbed compared to that with the DNA in bulk buffer. Time-dependent solvochromic effect of the probe H33258 further elucidates the dynamical solvation, which is reflective of the overall environmental relaxation of the DNAs upon condensation by H1. We have also performed circular dichroism (CD) studies on the DNAs and their complexes with H1, which reveal the change in conformation of the DNAs in the complexes. Our studies in the ligand-binding mechanisms of the DNA-H1 complex are important to understand the mechanism of drug binding to linker DNA in condensed chromatin.     

Automated determination of DNA using the fluorochrome Hoechst 33258

An automated method for the determination of DNA content in fractions from the alkaline filter elution assay of DNA damage has been developed. DNA-containing fractions are mixed with a fluorochrome (Hoechst 33258) and the DNA concentration is measured fluorometrically in a continuous-flow system. The lower limit of detection is 0.05 micrograms DNA/ml, and the linearity range under the conditions used is 0-8 micrograms DNA/ml. The standard deviation (n = 10) was found to be +/- 0.83%. The results are compared with the manual method.     

Influence of ionic strength on Hoechst 33258 binding with DNA

The binding of Hoechst 33258 with DNA at various ionic strengths of solution and different ligand concentrations has been investigated. Existence of more than one type of interactions of Hoechst 33258 with DNA has been revealed, which were very sensitive to the ionic strength. Hoechst 33258 doesn't show specificity to AT sequences of DNA at low ionic strength. High affinity binding mode becomes obvious at high ionic strength. The values of binding constants and binding site sizes for revealed strong and weak interactions have been determined.     

Mechanism of interaction of DNA with fluorescent dye Hoechst 33258]

From the study of absorption and fluorescence spectra of the complex "Hoechst-33258"--DNA at different pH it is shown that AT--specific complex with DNA is formed by the neutral dye molecule, whereas the cationic state of the dye molecule forms the nonspecific complex. Possible formation of a specific complex in which the dye is bound to DNA in its major groove is discussed.     

Binding of Hoechst 33258 and its Derivatives to DNA

Abstract

In the present work, we employed UV-VIS spectroscopy, fluorescence methods, and circular dichroism spectroscopy (CD) to study the interaction of dye Hoechst 33258, Hoechst 33342, and their derivatives to poly[d(AT)]·poly[d(AT)], poly(dA)·poly(dT), and DNA dodecamer with the sequence 5′-CGTATATATACG-3′. We identified three types of complexes formed by Hoechst 33258, Hoechst 33342, and methylproamine with DNA, corresponding to the binding of each drug in monomer, dimer, and tetramer forms. In a dimer complex, two dye molecules are sandwiched in the same place of the minor DNA groove. Our data show that Hoechst 33258, Hoechst 33342, and methylproamine also form complexes of the third type that reflects binding of dye associates (probably tetramers) to DNA. Substitution of a hydrogen atom in the ortho position of the phenyl ring by a methyl group has a little effect on binding of monomers to DNA. However it reduces strength of binding of tetramers to DNA. In contrast, a Hoechst derivative containing the ortho-isopropyl group in the phenyl ring exhibits a low affinity to poly(dA)·poly(dT) and poly[d(AT)]·poly[d(AT)] and binds to DNA only in the monomer form. This can be attributed to a sterical hindrance caused by the ortho-isopropyl group for side-by-side accommodation of two dye molecules in the minor groove. Our experiments show that mode of binding of Hoechst 33258 derivatives and their affinity for DNA depend on substituents in the ortho position of the phenyl ring of the dye molecule. A statistical mechanical treatment of binding of Hoechst 33258 and its derivatives to a polynucleotide lattice is described and used for determination of binding parameters of Hoechst 33258 and its derivatives to poly[d(AT)]·poly[d(AT)] and poly(dA)·poly(dT).     

Fluorophotometric quantitation of DNA in articular cartilage utilizing Hoechst 33258

A sensitive fluorophotometric assay was developed for the measurement of DNA in articular cartilage. The tissue was digested with Proteinase K and dodecyl sodium sulfate, followed by analysis with Hoechst 33258 dye. DNA content was determined on both fresh and lyophilized material containing as little as 50 ng DNA. The results are comparable to values for other fluorophotometric and spectrophotometric methods reported in the literature. In addition, this method can be incorporated into existing methodology, allowing quantitation of specific glycosaminoglycans in the same cartilage sample in terms of DNA.     

Fluorometric assay of DNA in cartilage explants using Hoechst 33258

A simple two-step fluorometric assay of DNA in cartilage explants, utilizing the bisbenzimidazole dye Hoechst 33258, is described. Cartilage explants were prepared for assay by digestion with papain. Aliquots of the digest were mixed with dye solution, and the fluorescence emission measured. The enhancement in fluorescence of dye was specific for DNA, as demonstrated by 97% sensitivity to DNase and resistance to RNase. In addition, little or no interference was caused by non-DNA tissue components, since DNA caused an equal enhancement in fluorescence independent of the presence of papain-digested cartilage. By performing the assay on isolated chondrocytes, the cellular content of DNA was computed to be 7.7 pg per chondrocyte. The assay was stable for at least 2 h and sensitive to as little as 6 ng of DNA or equivalently less than 1000 cells. This procedure offers advantages over other established DNA assays of cartilage and may be especially useful in metabolic studies of cartilage explants.     

DNA structural features responsible for sequence-dependent binding geometries of Hoechst 33258

The complexes of Hoechst 33258 with poly[d(A-T)₂], poly[d(I-C)₂], poly[d(G-C)₂], and poly[d(G-m⁵C)₂] were studied using linear dichroism, CD, and fluorescence spectroscopies. The Hoechst-poly[d(I-C)₂] complex, in which there is no guanine amino group protruding in the minor groove, exhibits spectroscopic properties that are very similar to those of the Hoechst-poly[d(A-T)₂] complex. When bound to both of these polynucleotides, Hoechst exhibits an average orientation angle of near 45° relative to the DNA helix axis for the long-axis polarized low-energy transition, a relatively strong positive induced CD, and a strong increase in fluorescence intensity—leading us to conclude that this molecule also binds in the minor groove of poly[d(I-C)₂]. By contrast, when bound to poly[d(G-C)₂] and poly[d(G-m⁵C)₂], Hoechst shows a distinctively different behavior. The strongly negative reduced linear dichroism in the ligand absorption region is consistent with a model in which part of the Hoechst chromophore is intercalculated between DNA bases. From the low drug:base ratio onset of excitonic effects in the CD and fluorescence emission spectra, it is inferred that another part of the Hoechst molecule may sit in the major groove of poly[d(G-C)₂] and poly[d(G-m⁵C)₂] and preferentially stacks into dimers, though this tendency is strongly reduced for the latter polynucleotide. Based on these results, the importance of the interactions of Hoechst with the exocyclic amino group of guanine and the methyl group of cytosine in determining the binding modes are discussed. © 1996 John Wiley & Sons, Inc.     

Physico-chemical study of the complexes of "33258 Hoechst" with DNA and nucleohistone.

The degree of binding of "33258 Hoechst" to DNA and nucleohistone has been determined by equilibrium dialysis and the properties of the complexes have been followed by different optical and electro-optical methods, after determining the orientation of the main transition moments within the dye molecule. The binding isotherm was found composed of a Langmuir-type and of a strongly cooperative component. The existence of two bound species yielded a continuous variation of most of the properties of the complexes studied as the amount of binding increased, while the hydrodynamic properties of the macromolecules were not affected. At low binding, the strongly bound dye molecules appeared to bind to highly fluorescent sites with their long axis oriented at 45 degree to the helix axis. As the binding proceeds, less fluorescent sites are cooperatively occupied and the inclination of these ligand molecules becomes closer to that of the base planes. These results are compatible with the formation of two external complexes with the double helical structure.     

Equilibrium binding of Hoechst 33258 and Hoechst 33342 fluorochromes with rat colorectal cells

We examined the biophysical characteristics of the interaction of Hoechst 33258 and 33342 dyes with normal rat colorectal cells as functions of fixation and solution composition. Classical dye-binding techniques were used to investigate the stoichiometry and binding constants with whole cells, and quantitative fluorescence image analysis was used to specifically study nuclear dye binding in intact cells. In aqueous solution, H-33258 dye bound cooperatively with intact cells, with a binding constant of between 3-4 x 10(5). In ethanolic solution, binding appeared less cooperative, although Scatchard analysis could not be used. The binding constant was slightly lower (2 x 10(5)), but the total number of cell binding sites was decreased by a factor of 5, reflecting a great decrease in cytoplasmic sites. QFIA studies identified conditions optimal for DNA quantitation under which the fluorescence signal was independent of dye or cell concentration. The proportionality between absolute nuclear fluorescence intensity and DNA content was established, and the upper limit of DNA content of normal colorectal cells was also determined.     

Effects of Polyamines on the Binding of Hoechst 33258 to Calf Thymus DNA

Abstract

The ability of polyamines to displace the minor groove-binding dye Hoechst 33258 from calf thymus DNA was investigated. Polyamines displace non-specific DNA phosphate bound Hoechst in a charge-dependent fashion, but show very little ability to displace the high affinity binding of Hoechst in the minor groove of DNA. This high affinity binding is, however, sensitive to ethidium bromide and the minor groove binding drug berenil. These studies suggest that polyamines probably bind DNA in the minor groove very weakly, if at all, relative to known minor groove binding agents.     

UVA irradiation of BrU-substituted DNA in the presence of Hoechst 33258

Given that our knowledge of DNA repair is limited because of the complexity of the DNA system, a technique called UVA micro-irradiation has been developed that can be used to visualize the recruitment of DNA repair proteins at double-strand break (DSB) sites. Interestingly, Hoechst 33258 was used under micro-irradiation to sensitize 5-bromouracil (^BrU)-labelled DNA, causing efficient DSBs. However, the molecular basis of DSB formation under UVA micro-irradiation remains unknown. Herein, we investigated the mechanism of DSB formation under UVA micro-irradiation conditions. Our results suggest that the generation of a uracil-5-yl radical through electron transfer from Hoechst 33258 to ^BrU caused DNA cleavage preferentially at self-complementary 5′-AA^BrU^BrU-3′ sequences to induce DSB. We also investigated the DNA cleavage in the context of the nucleosome to gain a better understanding of UVA micro-irradiation in a cell-like model. We found that DNA cleavage occurred in both core and linker DNA regions although its efficiency reduced in core DNA.     

The Hoechst 33258 covalent dimer covers a total turn of the double-stranded DNA

With the goal to design ligands recognizing extended regions on dsDNA, a covalent dimer of the fluorescent dye Hoechst 33258 [bis-HT(NMe)] composed of two dye molecules linked via the phenol oxygen atoms with a (CH2)3-N+ H(CH3)-(CH2)3 fragment was constructed using computer modeling and then synthesized. Its interactions with the double-stranded DNA (dsDNA) were studied by fluorescent and UV-Vis spectroscopy and circular (CD) and linear dichroism (LD). Based on variations in the affinity to the dsDNA, it was shown that complexes of three types are formed. The first type complexes result from binding of a bis-HT(NMe) monomer in the open conformation; in this case the ligand covers the total dsDNA turn and is located in the minor groove according to the positive value of CD at 370 nm. In addition, the ability to form bis-HT(NMe)-bridges between two dsDNA molecules, i.e., each of the two bis-HT(NMe) ends binds to two different dsDNA molecules, was demonstrated for the first type complexes. Spectral characteristics (maximal absorption at 362 nm, positive sign, and maximal value of CD at 370 nm) of the first type complexes conform to those of the specific Hoechst 33258 complex with poly[d(A-T)] x poly[d(A-T]. The second type complexes correspond to the bis-HT(NMe) sandwich (as an inter- or intramolecular) binding to dsDNA with stoichiometry > or = 5 bp. Thereby, a negative LD at 360 nm and the location of bis-HT(NMe) sandwiches in the minor groove of B form dsDNA seems contradictory. Spectral characteristics (maximal positive CD at 345 nm, a dramatic decrease in fluorescence intensity and the shift of its maximum to 490 nm) of these complexes favor a suggestion that this binding correlates to the formation of nonspecific dimeric Hoechst 33258 complex with dsDNA. The third type complexes are characterized by stoichiometry of one bis-HT(NMe) molecule per approximately 2 bp and the tendency to zero of LD values at 270 and 360 nm. We assume that in these complexes bis-HT(NMe) sandwich dimers are formed on dsDNA. The complexes of this type conform to the aggregation type complex of Hoechst 33258 with dsDNA. The ability of bis-HT(NMe) to cover the whole dsDNA turn or form bridges with two dsDNA upon the formation of the first type complexes essentially distinguishes it from Hoechst 33258, which can only occupy 5 bp and does not form such bridges. This specific property of bis-HT(NMe) may support new biological activities.     

Fluorometric Determination of DNA in Aquatic Microorganisms by Use of Hoechst 33258

A method for the determination of microbial DNA in aquatic environments by the use of Hoechst 33258 has been developed. With unsophisticated instrumentation and simple extraction procedures, it is possible to detect from 0.05 to 10 μg of DNA in bacterial cultures or natural water samples. The method is specific for DNA; DNase I treatment of extracts of natural microbial populations removed 95 to 100% of the observed fluorescence. DNA content ranged from 165 ng ml⁻¹ for relatively eutrophic Potomac River water to 27 ng ml⁻¹ for coastal Atlantic Ocean water and was correlated to an acridine orange direct count (r = 0.90).     

Optical studies of the interaction of 33258 Hoechst with DNA,chromatin, and metaphase chromosomes

The interaction of the bisbenzimidazole dye 33258 Hoechst with DNA and chromatin is characterized by changes in absorption, fluorescence, and circular dichroism measurements. At low dye/phosphate ratios, dye binding is accompanied by intense fluorescence and circular dichroism and exhibits little sensitivity to ionic strength. At higher dye/phosphate ratios, additional dye binding can be detected by further changes in absorptivity. This secondary binding is suppressed by increasing the ionic strength. A-T rich DNA sequences enhance both dye binding and fluorescence quantum yield, while chromosomal proteins apparently exclude the dye from approximately half of the sites available with DNA. Fluorescence of the free dye is sensitive to pH and, below pH 8, to quenching by iodide ion. Substitution of 5-bromodeoxyuridine (BrdU) for thymidine in synthetic polynucleotides, DNA, or unfixed chromatin quenches the fluorescence of bound dye. This suppression of dye fluorescence permits optical detection of BrdU incorporation associated with DNA synthesis in cytological chromosome preparations. Quenching of 33258 Hoechst fluorescence by BrdU can be abolished by appropriate alterations in solvent conditions, thereby revealing changes in dye fluorescence of microscopic specimens specifically due to BrdU incorporation.